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H
CO CO CO Q
REPORT NUMBER 163
NOVEMBER 1965
PRELIMINARY FLUTTER ANALYSIS
VOLUME III CONTROL SURFACES
LIFT FAN FUGHTRES^ARCH AIRCRiRFT PROGRAW
CONTRACT NUMBER DA44-177-TC-71.S
GENERAL (^ELECTRIC
LI ^
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:i i
FFNo 2Mt Revised Aug 65
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Report Number 163
OPSTI
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PRELIMINARY FLUTTER ANALYSIS
VOLUME III - CONTROL SURFACES
XV-5A Lift Fan Flight Research Aircraft
Contract DA 44-177-TC-715
December 1965
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ADVANCED ENGINE & TECHNOLOGY DEPARTMENT GENERAL ELECTRIC COMPANY
CINCINNATI, OHIO 45215
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JUN 11966
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CONTENTS
SECTION
1.0 SUMMARY
2.0 INTRODUCTION
3. 0 METHOD OF APPROACH
Symmetric
4.0 DISCUSSION AND RESULTS
4.1 Aileron and Aileron Flight Tab
Parameters
Symmetric Analysis
Parameters for the Symmetric
Analysis
Results
Conclusions
Antisymmetric Analysis
Parameters for the Antisymmetric
Analysis
Results
Conclusions
4.2 Rudder and Rudder Trim Tab
Analysis
Parameters
Results
Conclusions
(Cor'mued)
PAGE
1
3
5
3 i Control Surface - Flight Tab System. 6
Symmetric and Antisymmetric 3.2 Parent Surface - Control Surface System. ^
29
29
29
34
35
35
52
54
55
55
68
68
72
73
73
ill
LIST OF FIGURES
FIGURE PAGE
1 Schematic of Aileron System 30 2 Wing Outer Panel - Plan View 31 3 Aileron Aerodynamic Balancing Arrangement 32 4 Idealization of Symmetric Aileron System 32 5 g-V and f-V Plots, Symmetric Aileron, 45
f^j = 15 cps, B^O 6 g-V and f-V Plots, Symmetric Aileron, 46
iß = 20 cps, B ^ 0 7 g-V and f-V Plots, Symmetric Aileron, 47
fp = 30 cps, B ^ 0 8 g-V and f-V Plots, Symmetric Aileron, 48
fß = 15 cps, B = 0 9 g-V and f-V Plots, Symmetric Aileron, 49
f^ = 20 cps, B = 0 10 g-V and f-V Plots, Symmetric Aileron, 50
iß = 30 cps, B = 0 11 Vjvs. in Cross-plot, Symmetric Aileron 51 12 Idealization of Antisymmetric Aileron System 52
* 13 g-V and f-V Plots, Antisymmetric Aileron, 62 •' f/3 =: 15 cps, B ^ 0
14 g-V and f-V Plots, Antisymmetric Aileron, 63 f^ = 20 cps, B ^ 0
15 g-V and f-V Plots, Antisymmetric Aileron, 64
f^ = 30 cps, B ^ 0 16 g-V and f-V Plots, Antisymmetric Aileron, 65
fß = 15 cps, B = 0 17 g-V and f-V Plots, Antisymmetric Aileron, 66
in = 20 cps, B = 0 18 g-V and f-V Plots, Antisymmetric Aileron, 67
f^ = 30 cps, B = 0 19 Schematic of Rudder System 70 20 Vertical Tail - Plan View 70 21 Rudder Aerodynamic Balancing Arrangement 71 22 Idealization of Rudder System 71 23 g-V and f-V Plots, Rudder, % = 20 cps, B / 0 82 24 g-V and f-V Plots, Rudder, f6 = 40 cps, B / 0 83 25 g-V and f-V Plots, Rudder.. f6 = 60 cps, B ^ 0 84 26 g-V and f-V Plots, Rudder, f. = 20 cps, B = 0 85 27 g-V and f-V Plots, Rudder, fö = 40 cps, B = 0 86
— mr~*—~*m
*..£-
1
BLANK PAGE
m
I
•
te. J
IN
- — —•~—*.«
LIST OF FIGURES (Continued)
FIGURE PAGE
28 g-V and f-V Plots, Rudder, ^ = 60 ops, B = 0 87 29 Vf vs. % Cross-plot. Rudder 88 30 Schematic of Elevator System 93 31 Horizontal Tail - Plan View 93 32 Elevator Aerodynamic Balancing Arrangement 94 33 Idealization of Elevator System 94 34 g-V and f-V Plots, Elevator, la = 20 cps, B ^ 0 103 35 g-V and f-V Plots, Elevator, fa = 40 cps, B ^ 0 104 36 g-V and f-V Plots, Elevator, fa = 60 cps, B ^ 0 105 37 g-V and i-V Plots, Elevator, f a- 20 cps, B = 0 106 38 g-V and f-V Plots, Elevator, fa = 40 cps, B = 0 107 39 g-V and f-V Plots, Elevator, fa, = 60 cps, B = 0 108
vi
TABLES
TABLE PAGE
1 Aileron-Aileron Tab Aerodynamic Parameters 2 Solutions of Stability Equations, Symmetric Aileron,
fo = 15 cps, B ^ 0 3 Solutions of Stability Equations, Symmetric Aileron,
iß = 20 cps, B ^ 0 4 Solutions of Stability Equations, Symmetric Aileron,
fß = 30 cps, B ^ 0 5 Solutions of Stability Equations, Symmetric Aileron,
iß = 15 cps, B = 0 6 Solutions of Stability Equations, Symmetric Aileron,
f^ = 20 cps, B = 0 7 Solutions of Stability Equations, Symmetric Aileron,
iß = 30 cps, B = 0 8 Solutions of Stability Equations, Antisymmetric
Aileron, io = 15 cps, B ^ 0 9 Solutions of Stability Equations, Antisymmetric
Aileron, f^ - 20 cps, B / 0 10 Solutions of Stability Equations, Antisymmetric
Aileron, f^ - 30 cps, B ^ 0 11 Solutions of Stability Equations, Antisymmetric
Aileron, fß = 15 cps, B = 0 12 Solutions of Stability Equations, Antisymmetric
Aileron, in = 20 cps, B = 0 13 Solutions of Stability Equations, Antisymmetric
Aileron, fß = 30 cps, B = 0 14 Rudder-Rudder Tab Aerodynamic Parameters 15 Solutions of Stability Equations, Rudder,
fg = 20 cps, B ^ 0 16 Solutions of Stability Equations, Rudder,
iö =40 cps, B ^ 0 17 Solutions of Stability Equations, Rudder,
fö = 60 cps, B ^ 0 18 Solutions of Stability Equations, Rudder,
^5 = 20 cps, B - 0 19 Solutions of Stability Equations, Rudder,
i6 - 40 cps, B - 0 20 Solutions of Stability Equations, Rudder,
fö - 60 cps, B = 0 21 Horizontal Stabilizer-Elevator Aerodynamic
Parameters
37 39
40
41
42
43
44
56
57
58
59
60
61
75 76
77
78
79
80
81
95
vii
TABLES (Continued)
TABLE PAGE
22 Solutions of Stability Equations, Elevator, 97 fa=20cps, B^O
23 Solutions of Stability Equations, Elevator, 98 fa = 40 ops, B ^ 0
24 Solutions of Stability Equations, Elevator, 99 fa = 60 ops, B ^ 0
25 Solutions of Stability Equations, Elevator, 100 {a = 20 ops, B = 0
26 Solutions of Stability Equations, Elevator, 101 fa = 40 cps, B = 0
27 Solutions of Stability Equations, Elevator, 102 fa = 60 cps, B = 0
viii
1.0 SUMMARY
The overall preliminary theoretical flutter analysis of the Ryan XV-5A Lift Fan Aircraft is presented in three volumes, each under separate cover. This is Volume III which reports the investigation of the flutter characteristics of the control surfaces. Volumes I and II detail the analysis of the wing and empennage, respectively.
Equations of motion and stability equations are formulated using lumped spring-mass idealization and incompressible strip theory aerodynamics; control system elasticity and inertia are taken into account. One altitude only, sea level, is investigated. Solutions of the stability equations are obtained, giving flutter frequencies and complex damping coefficients required to maintain flutter as functions of flutter velocities for various values of stiffness parameter, both with and without aerodynamic balancing (centering) of the control surface.
Both a symmetric and an antisymmetric analysis of the aileron- aileron flight tab - aileron control system are made. An analysis of the rudder - rudder trim tab - rudder control system is included and a symmetric analysis of the horizontal stabilizer - elevator - elevator control system is also made.
On the basis of preliminary input information used in the analyses herein, increased stiffness of the aileron flight tab restraint is required (the symmetric aileron condition is critical), and the stiffness of the rudder trim tab actuator should be such that the uncoupled rigid body tab rotation frequency is at least 50 cps, in order to insure a flutter-free airplane within the established flight envelope. The antisymmetric aileron condition and elevator are flutter-free.
2.0 INTRODUCTION
This report presents a portion of the preliminary flutter analysis of the U.S. Army XV-5A Lift Fan Research Aircraft. Volumes I and II of the preliminary flutter analysis are concerned with the wing and with the empennage, respectively. The report herein is volume ill.
The XV-5A is a V/STOL aircraft designed for research flight testing of the General Electric X353-5 lift fan propulsion system. A three-view drawing and a cutaway drawing of the aircraft are presented in Volume I. The XV-5A also features high subsonic conventional flight operation. It has a basic design gross weight of 9200 pounds, a limit dive speed of 500 KEAS (q = 850 psf) and corresponding 0. 90 maximum Mach number. Thus, only one altitude, sea level, is Investigated herein.
The analysis is based on incompressible strip theory aerodynamics with a lumped spring-mass system idealization, taking into account control system elasticity and inertia.
The purpose of the analysis is to calculate flutter velocities where they exist, for various values of stiffness parameters that reflect design unknowns, both with and without aerodynamic balancing (centering) of the control surfaces. Comparison of results with limit dive speed require- ments then affords a basis for design changes to ensure a flutter-free aircraft, or for assurance that current design is flutter safe.
The report is subdivided into two main parts, Sections 3.0 and 4.0. Section 3.0 presents a general approach to the analysis method, devel- oped for a control surface - flight tab system, both symmetric and anti- symmetric, and also developed for a symmetric parent surface - control surface system. Equations of motion and of stability are formulated in general form, the aerodynamics are explained, as are mass terms, stiffness terms, coordinates, and basic assumptions, and the general characteristics of the solutions are discussed.
Section 4. 0 shows the application of the method of approach to the specific cases at hand:
1. The aileron and aileron flight tab system (Both symmetric and antisymmetric aileron analyses are made.)
2. The rudder and rudder tab system
fc*
BLANK PAGE
A
3. The horizontal stabilizer and elevator system (Only a symmetric analysis is made, since antisymmetric elevator flutter is clearly not critical; this conclusion is discussed in Section 4.0.)
In Section 4.0, for each of the three cases above, schematics of the con- trol system, of the aerodynamic balancing arrangement, and of the ideal- ization are given, and plan views of the surfaces are shown. Values of the numerous input parameters are given, and results are presented both tabularly and graphically. The results are interpreted, and conclusions are drawn.
3. 0 METHOD OF APPROACH
The equations of motion for a flutter investigation of a control surface and flight tab system, which applies to the lateral control system (CTOL mode) of the XV-5A aircraft, are developed for both a symmetric and antisymmetric analysis. In general, the procedure follows the develop- ment of the governing equations, as presented in Reference 1. The same equations of motion also apply to the directional control system (CTOL mode) of the XV-5A aircraft, since the rudder trim tab is one of zero gearing and thus may be treated as a flight tab with nonexistent connec- tions between it and the pedal.
A similar development, for the symmetric case only but with different components, (a parent surface and a control surface) is the case of the longitudinal system (CTOL mode) of the XV-5A aircraft, and is pre- sented separately.
Specific details applicable to each individual analysis are discussed in Section 4.0
3.1 CONTROL SURFACE - FLIGHT TAB SYSTEM. SYMMETRIC AND ANTISYMMETRIC
The degrees of freedom considered are:
ß = Control surface rotation
Ö = Control surface flight tab rotation, relative to the control surface
Y = Control stick or pedal rotation
Lagrange's equations of motion for the system governed by the above degrees of freedom are:
BT \ au 4 dt \
.1 f 8T )+ £U _ dt \ ä5" / as = % (2)
dt \ a y / a y l ;
where
T is the kinetic energy of the system
U is the potential energy (internal strain energy) of the system
Qß , Qr are the generalized aerodynamic forces applied to the system
The kinetic energy of the system is
T=|(l/+20i PM -M^V^JV2) (4)
where
I,, = Mass moment of inertia of control surface including tab, p
about control surface hinge line
I. = Mass moment of inertia of flight tab about its hinge line
0
i
P = Mass product of Inertia of flight tab about control surface hinge line and tab hinge line
= I, +SJ ö 6 t
where:
S. = Static unbalance of flight tab about its hinge line
i = Distance between control surface and tab hinge lines, measured perpendicular to control surface hinge line
J = Mass moment of inertia of control stick or pedal, including linkages, about control stick or pedal axis of rotation
The potential energy of the system is derived from the displacements of concentrated springs within the control surface - flight tab systems. A symmetric or antisymmetric analysis Is determined by the springs that participate In the motion of the control surface and flight tab. For present purposes, the potential energy Is, In general terms,
v-il 1 sijVj <5> 1=1 j=i
where
q , q = The degrees of freedom considered: ß, 6, y
S = Constants generated through the rates of the concentrated springs and linkage arms through which they act. These constants are the elements of a stiffness matrix.
The virtual work done by the air forces Is
ÖW^Q^q. (6)
where
th ÖW = The virtual work for the I degree of freedom
Q = The total generalized aerodynamic force in the i degree of freedom
6q = The virtual displacement of the i degree of freedom
The symbol 6 means "a variation of".
Ü
Consider the following displacements:
Angle of rotation of control surface about its hinge line (plus trailing edge down)
Angle of rotation of flight tab about the tab hinge line, relative to the control surface (plus trailing edge down)
and let
d| = M|q| (7)
where
W: 1.0 0
0 1.0 (8)
The displacements expressed by Equation (7) represent rigid body dis- placements about the hinge lines of the control surface and flight tab. These displacements normally are about swept axes, and we require rotations about axes perpendicular to the free stream. Therefore,
cos^ 0 «.
0 cos ip &.
fd.
ld2 (9)
where:
ß' Angle of rotation of control surface about an axis perpendic- ular to the free stream
Ö' = Angle of rotation of flight tab about an axis perpendicular to the free stream
ip = Sweepback angle of control surface hinge line c
8
^M = Sweepback angle of flight tab hinge line
Combining Equations (7), (8) and (9),
Iß1' 'cos ip 0 "1 c
ri.o -| \ß —
[ö'l 0 cos 4> 1.0 [6
"cos i/i •L
0
cos ^ V
(10)
Using two-dimensional oscillatory aerodynamic coefficients and in the rotation of References 2 and 3 (Section 6. 0), the aerodynamic moments acting on the control surface and flight tab, per unit span are
(11)
r Trpco b cos ip . c/4 ■T0 T6] Iß']
Q« .% %] \s'\
where
= Mass density of air at altitudes under consideration
O) Circular frequency of oscillation
= Half-chord length
4> j = Sweepback angle of quarter-chord line of parent surface
VTä'VQ6 Oscillatory aerodynamic coefficients (nondl- mensional) In the rotation of References 2 and 3, in general, complex numbers. They contain no terms to account for the effects of aerodynamic balance; I.e., nose sections are assumed simply rounded. Corrections to account for the Internal balancing system for the control sur- faces used In the XV-5A aircraft are discussed on Page 11.
From the principle of virtual work, the work done by the moments of Equation (11) In undergoing a virtual displacement Is
r (I'-)
9
« I -■rumum
where S is the semispan parallel to the y-axis which Is perpendicular to the free stream. Primes indicate "in the stream directi&nM.
In matrix notation
öW =J Lö/3'ö6!J T
Q'
dy (13)
A
Since, from Equation (10) we have
cos 4>^ 0 c
\ß' ' 1
6' = * ' 0 cos ip
SJ
and therefore
16^'' cos Ü 0 c
0 cos 4>r
Ö/3
66' =
i
66
or, transposing,
Lö/3' 66^ = L6/3 66J cos 4>„ 0 c
0 cos 4> O
(14)
Combining Equations (11), (13) and (14), and noting that /S, 6 and their variations are not functions of y, the virtual work is
ÖW = [_öß Ö6j rrpu) cos 4,
n/A I b 2 , r A
c/4 0
cos ip •L
0
0 cos *..
\ r6
[% QJ J
COS ip •fc
0
0 cos ip •L
tJ
dy
(15)
10 1
»., h.
3
I therefore, since 6W = } oW. = / Q, öq, = Q,.6i3 + Q^öö +0'öT r-! l *-^ lip 0
3 —^
= L6^ MJ Q ß
the column of two-dimensional, generalized aerodynamic forces is
\%
TTpCJ cos ih . S ^c/4 r
0
- cos c
0
0 -.
COS i^ k Q6j
-cos iji 0 n dy ß c '
0 cos \\
Ö (16)
These generalized forces are the right-hand sides of the Lagrange's equations of motion, Equations (l)and (2).
We next treat the reguired correction to the generalized force Qo as a result of internal aerodynamic balance of the control surface, maintain- ing zero aerodynamic balance for the flight tab. Using References 1 and 4, the incremental two-dimensional aerodynamic moment acting on the control surface, per unit span is
2 4 — - AT' = -Trpw b cos 4' ,A LA Bj
c/4
where
A = F K
6'
BB /AC c/Exp
C(c, g, k)
(17)
11
'aCH
H
\,3
and
Fgß is an auxiliary function defining the internal aerodynamic balance I (e' -e") (e'+e")!
geometry and is equal to lc(e' -e") - — I. (See Figure 3.)
K is a pressure recovery factor to account for leakage across the in- ternal balance arrangement. /ACH \ , /ACH \ are control
Cöc/Exp. \ C,5c/3
surface, steady-state hinge moment derivatives, experimental and theoretical, respectively (aerodynamic balance contribution through control surface deflection).
AC« \ ,/ACH \ are control surface, steady-state hinge Cöt/Exp. \ Cöt/3
moment derivatives, experimental and theoretical, respectively (aero- dynamic balance contribution through flight tab deflection).
C(c, g, k) is a dimensionless coefficient similar to To (Equation (11)) and is a function only of airfoil and control surface geometry.
D(c, d, k) is a dimensionless coefficient similar to Tg (Equation (11)) and is a function only of airfoil, control surface and flight tab geometry.
The elements of the row matrix in Equation (17) are, in general, com- plex numbers. Now, again using the principle of virtual work, the work done by the internal balance forces in undergoing a virtual displacement is
J ÖW = j AT1 ö/i' dy (18)
0
where I is the semispan of the internal aerodynamic balance arrange- ment (i.e., simple nose overhang) parallel to the y axis, which axis is perpendicular to the free stream.
♦
Combining Equations (10), (14), (17) and (18), the virtual work of Internal balance forces is written:
ÖW =-öß Trpw cos $ . cos c/4
c 0 LA BJ
rcos $ «L
0 idy-i
0 cos ^ •L
tJ (19)
Since ÖWß = AQß 6ß in this case of correction for control surface inter- nal aerodynamic balance, the incremental two-dimensional generalized aerodynamic force to be added to Qo in Equation (16) is
.1 4 . - 2 /
AQ-=-7rpw cos «P /, cos ^, / b* I A BJ ß c/4 & J „
c 0
rcos 4* c
0 cos ip
Idy
*, (20)
Addition of the increment AQß from Equation (20) to Q^ in Equation (16) gives the case of the XV-5A aileron and rudder systems, namely, internal aerodynamic balance for the control surface and no aerodynamic balance for the tab.
The generalized aerodynamic forces are expressed simply in 3x1 matrix form as
|V 2 r
r ^ = \
I 11
I 12
r r 21 22
o 0
0
0
0
r ß\
Ö
y
(21)
where the \\i elements, in general complex numbers contain both the contributions of the basic surface (control aft of the hinge line) and of the internal aerodynamic balance (given by AQo). Qo and Q^ are now corrected values.
13
For convenience of calculations, the I' matrix of Equation (21) Is de- composed Into the sum of two matrices, the first containing the terms due to the basic surfaces (control surface and unbalanced flight tab), and the second containing the terms due to the Internal aerodynamic balancing arrangement of the control surface.
Thus, Equation (21) becomes
2 Q,
Q.
CJ
'6
I OJ
where
> =
A1l \2
0]
\l A22 0
0 0 oj
"Bll B120' r/n
0 0 0 1 6 I
0 0 0. rJ
(22)
H
A,, = TTPCOS T . 11 c/4 *c/4 /
4 2 b cos 4'
c' Exp.
Control Surface
<L /C c/ H
T^dy
c/ 3
H
f4 b cos 4>r cos ip,
_ . $. *-. /C t/Exp.
Tab t H T6dy
t/3
/ f . 4 . . v c/Exp. ^ , A„, = rrpcos W /. j b oosw cos w — v Q 0dy
Tab c t/ H, 21 /3
c/3
/ L4 2 \ Lil Exp. , A22 = rrpcos ^c/4 j b cos ^ ■ Q^dy
Tab t / H. t
t/ 3
14
ac II
B11 = rrpcos^^ / 4 2
b cos ;/r F K c/ Exp,
Aero. Bal.
<k BB /AC c / H
C(c,g,k)dy
c/ 3
'AC H
B ,„ = TT pcOSi/^ . / b COS ?i COS!/) F^^K 12 Yc/4 ^A. , fe_ K BB /AC
t' Exp. D(c,d,k)dy
Aero. Bal.
H
t/3
Note that the basic surface expressions A , A , A and A have been
modified by hinge moment correction factors /C \ //C
c/Exp./ \ c/ 3 etc. in order that these terms be consistent with the expressions for the internal aerodynamic balance arrangement.
In order to evaluate the elements of [A] and (B] given above, the control surface, flight tab and internal balance are divided into equal spanwise segments appropriate to the system under investigation, and all integra- tion is performed numerically using the trapezoidal rule.
The equations of motion for a control surface-flight tab flutter analysis are written in the familiar F= ma form by substituting Equations (4), (5) and (21) into Lagrange's Equations (1), (2), and (3).
Expressing the results in matrix form,
lß P/i6 0" ' ß'
V« " i ö » +
0 0 J .y.
Sll S12 \* ' ß' 2r U) |
s s s 21 22 231
i ö ^ — !
S31 S32 S33J . y. ■
r r o' 11 12
ß' 0]
r v o 21 22
i Ö \— < 0 \
0 0 0 , y. oj
(23)
15
1
iwt We assume harmonic motion q. =q, e and introduce a reference
1 lo spring rate K, which is merely a scaling factor for computing convenience. Further, we formulate the variable ß, which is the basic unknown,
« = - (1 + iS) (24)
Note that ß introduces a damping force that is proportional to displace- ment and in phase with the velocity, with g being a measure of this damping force, and is the so-called complex damping coefficient.
iwt Substitution of q = q. e and Equation (24) into Equation (23) gives
i i0
\ V0" n
Va 0 -
0 0 J
s s s 11 12 13
'v V 0 \l 12 'ß 0
S S S 21 22 23
+ r r o 21 22
' 6 = ' 0
s s s 31 32 33
0 0 0 . y. 0
(25)
where it is now understood that the S^. elements of the matrix derived from the potential energy expression are divided by the scaling factor K.
Upon expansion of the characteristic determinant, the determinant of the summed 3x3 matrix in Equation (25), there results a stability equation of the form:
3 2 Aß + Bfi +cn +D = 0 (26)
where A is real and B, C and D are, in general, complex.
The degree of the above equation depends implicitly on the type of analysis, i.e. symmetric or antisymmetric, being performed.
The solution of Equation (26) gives, in general, the complex roots ß from which g and co are obtained. Negative g is the stable state, and positive g is the unstable (flutter) state, w Is the circular flutter frequency. (I'] in Equation (25) Is chosen for several prescribed values of the dlmen- sionless parameter V/, , the reduced velocity. (b„ is some reference
bQco 0 half chord). Thus, solutions of Equation (26) give plots of g vs. w, and, by substitution of w into corresponding V/ values, plots of
0
16 i
g vs V are obtained. These are the basic stability relationships. The smallest nonzero value of V at g = 0 is the flutter velocity, Vf. Also, cross-plots of w vs V are useful, showing modal coalescence to the unstable state. Because of the three (at most) complex roots n from Equation (26), for each analysis, there are no more than three branches to the g - V and w - V plots.
Setting [I'] = [0] and g = 0 in Equation (25), the uncoupled natural fre- quency f^ =cJo/2 7r, control surface rotation, may be calculated, for interpretive purposes, from
lß-—2 Su=0 (27)
The uncoupled natural frequency f =OJ /2 7r, flight tab rotation, may be calculated from
h--2 S22 = 0 (28)
and the uncoupled natural frequency f = co /27r, control stick or pedal rotation, from
J--| S33=0 (29)
y
17
3.2 PARENT SURFACE-CONTROL SURFACE SYSTEM. SYMMETRIC
The degrees of freedom considered are
o; = Parent surface rotation
ß = Control surface rotation relative to parent surface
7 = Control stick rotation
The general analysis herein is applied in Paragraph 4.3 to the horizontal stabilizer-elevator system of the XV-5A aircraft. All of the general analysis made in Paragraph 3.1 applies for the system under considera- tion here, with some important differences:
1. The generalized coordinates ß and ö in Paragraph 3.1 are replaced by the generalized coordinates a and ß, respectively, a referring to the generalized coordinate "parent surface rotation". The generalized coordinate "tab rotation" does not apply to the present case, since there is no tab.
2. The kinetic energy, T, of the system is given by an equation of form similar to Equation (4) in Paragraph 3.1, but the definitions of terms are slightly modified and the symbol J is replaced by JQ with a different definition:
T =i(l/ +2ä,j Paß+Xßß2) +|<V2) (30)
where
I = Mass moment of inertia of half the parent surface, including the half of entire control surface, about the pivot axis of the parent surface
I „ = Mass moment of inertia of one control surface about its p hinge line. It is assumed that the complete system con-
tains two control surfaces, a right-hand and a left-hand one
P = Mass product of inertia of one control surface about parent surface pivot axis and control surface hinge line
j£
18
where:
S = Static unbalance of one control surface about its hinge line
S. = Streamwise distance between parent surface pivot axis and control surface hinge line
J = Effective mass moment of Inertia of half the control circuit and control stick, about control stick axis of rotation
3. The generalized forces and, in particular, the aerodynamic matrix [V] in Equation (23) are reformulated to take into account normal-to-plane motion of the parent surface.
The virtual work done by the air forces is as before:
öw =Q öq. i = 1, 2, 3
Consider the following displacements at a representative station:
d = Deflection of the elastic axis of the parent surface in the z (normal-to-plane) direction (plus down)
d = Angle of rotation of parent surface about Its elastic axis (plus leading edge up)
d = Angle of rotation about an axis perpendicular to the elastic axis of the parent surface (plus when tip of surface Is depressed); d.. Is a bending displacement
d, = Angle of rotation of control surface about Its hinge line, 4
relative to the parent surface (plus trailing edge down)
And let
{d} = ( (p] {q} as before (31)
where
{q} = iß} here
19
and
m = *,.
0
*2i 0
*31 0
0 <p 41
(32) I
Note that there are no generalized aerodynamic force components due toy.
From the geometry and definition of the displacements d.,
<f>n = (1.0) g
021 =(1.0)cos^a
^31 =<1-0)8lMe.a.
041 - 1.0
where
g = Distance from parent surface pivot axis to its elastic axis in the stream direction (plus aft of pivot axis); this dimensional variable Is not the same as expressed In Equation (22)
;/ = Sweepback angle of parent surface elastic axis e.a.
Substituting element values Into Equation (32),
IV)
g cos 4'
sin ip e. a.
e. a. 0
0 0
0
1.0
(33)
Since the deflections d., at this point, are deflections relative to the
elastic axis (except for d^, which Is relative to the control surface hinge line) we transform the four displacements to axes parallel and perpen- dicular to the free stream at the representative station.
20 I --»7»
Let
d' 1
Vertical displacement of the parent surface at its elastic axis
d' 2
Angle of rotation of parent surface about an axis perpen- dicular to the free stream, through the elastic axis of the parent surface (pitch angle of parent surface)
di Angle of rotation of parent surface about an axis parallel to the free stream, through the elastic axis of the parent surface (roll angle of parent surface)
d; = Angle of rotation of control surfp'ie about an axis perpen-
dicular to the free stream, through the control surface hinge line; the rotation being relative to dj, (pitch angle of control surface rotation relative to parent surface)
From the geometry and definitions of the displacements d' ,
"1 1.0 0 0 0 'di\
d2 ► zz
0 cos ip e.a.
sin il> e.a. 0
i
d2
d3 0 -sin ip
e. a. COS li)
e. a. 0 d3
V 0 0 0 C_
d4
(34)
where ip = sweepback angle of the control surface hinge line. Since the ific
air forces are written for displacements of the quarter chord, maintain- ing rotations relative to free stream axes, we transform the vertical displacement at the elastic axis to that at the quarter-chord line, still at the same representative station.
Let h = Vertical displacement of parent surface at the quarter-
chord line, h Is a linear coiabination of d' and d'.
a' = Angle of rotation of parent surface about axis perpen- dicular to free stream direction, axis passing through the quarter chord point (pitch angle of parent surface); thus
21
ß1 - Angle of rotation of control surface about axis perpendicular to free stream direction, relative to parent surface; axis passing through the hinge line (pitch angle of control sur- face relative to parent surface); thus ß' = d'
Note that neither h, ü;' nor ß' is a function of d'.
The required transformation is
h 1.0 -a 0 0 [di a' * = 0 1.0 0 0 d2
0' 0 0 0 1.0
d;
(35)
where a = streamwise distance from quarter-chord line to elastic axis at representative station. Combining Equations (31), /32), (33), (34) and (35), and multiplying out gives
h
a'
ß1
g-a 0
1.0 0
0 cos ip *
(36)
Equation (36) could have been written out directly from considerations of the rigid body degrees of freedom involved; the preceding was developed from the XV-5A empennage flutter analysis and used herein for continuity.
Using two-dimensional aerodynamic oscillatory coefficients in the nota- tion of References 2 and 3 and assuming, at this point, zero aerodynamic balance for the control surface, the aerodynamic forces acting per unit span are
L'b
M'
TT pCü b COS ip )/4
M. ü; ß
h/b
M Mn a ß ■ a'
T T Ü! ß J' .
From the principle of virtual work,
S ÖW
0 (L' b)ö(--- j + M'ö a' +Tf 6/3' dy
(37)
(38)
22
■ ***k y
where S is again the semispan parallel to the y-axis, which is perpendicu lar to the free stream. Primes indicate "in the stream direction".
In matrix notation:
ÖW= J UfM 6a' 6/3' L'b
M'
T'
dy
(39)
Nondimensionalizing the h deflectioi and applying a variation in the vari- ables of Equation (36), we have
h\l © öa'
6/3'
or, transposing,
g-a b
1.0
0
0
0
cos ^ •L
öß
l ö(- öa' 6/3'j = LÖOi ößj g-a 1.0 b
0 0 cos 4> •fe
(40)
Combining Equations (36), (37), (39) and (40) and noting that a and ß and their variations are not functions of y, the virtual work Is
ÖW = 6a öß
r
2 T 4 Trpw cos 4> , b
c/4 J0
g-a 1.0 b
0
0
0 cos 4> «
Lh La Lß
Mh Ma
Mß
Th Ta
Tß
g-a b
1.0
0
0
0 cos ip fe
dy o;
(41)
Since ÖW = Löa ö^J Q a
Q
, from the basic definition of virtual work, the
column of two-dimensional, generalized aerodynamic forces Is
23
Q ü!
Q.
2 Trpu) cos ip
c/4 S A
o
haß
Mu M M,, haß
T. T T. h a /3
g-a 1.0
0
g-a b 1.0
0 cos ^
0
0
0 cos ^
•ft
*,
dy a
(42)
These generalized forces are the right-hand sides of Lagrange's equations of motion for the system at hand.
These equations are:
dt \da/ da a (43)
dt \dß dß ^ß (44)
dt \dyl dy (45)
where y is the degree of freedom "control stick rotation". We next treat the correction to the generalized force Qo as a result of the internal aero- dynamic balance arrangement of the control surface. The XV-5A elevator system is of this type, since it uses a simple nose overhang with a curtain seal.
Again using References 1 and 4, the incremental, two-dimensional aero- dynamic moment acting on the control surface, per unit span, is
2 . 4 AT' = -Trpcj b cos 4, |_A B Cj h/b
a'
(46)
24
where
A = FBB K /^■JL\EXP' A<0'k> H
OLI 3
B = FBB K ITT-1^' B<C' a' k) H
c , ai/3
/ACH \
\ c/Exp. c = FBB K r^T' C(Ci ^ ^ H \
""o/S
and
FBB and K are the same as defined in Paragraph 3.1
ACJJ \ , /ACj, \ are control surface steady-state hinge Ca/Exp. \ ca!/3
moment derivatives, experimental and theoretical, respectively (aero- dynamic balance contribution through angle of attack)
^ACj^ \ » /^H \ are ^e same a8 defined in Paragraph 3.1
X/Exp. \ Cöc/3
A(c, k) is a dimensionless coefficient similar to T^ (Equation (37)) and is a function only of airfoil and control surface geometry. B(c, a, k) is a dimensionless coefficient similar to Ta (Equation (37)) and is a function only of airfoil and control surface geometry (the parameter "a" being equal to -0.5 for this analysis, different from that expressed in Equation (36))
C(c, g, k) is the same as defined in Paragraph 3.1
The elements of the row matrix in Equation (46) are, in general, com- plex numbers. Using again the principle of virtual work, the work done by the internal balance forces in undergoing a virtual displacement Is
25
26
öW = / (AT') {6ß') dy
where i is the semispan of the internal aerodynamic balance arrange- ment (i.e., simple nose overhang), as before.
The work may be written in the equivalent form:
ÖW= J Lö(^-) 6a' Ö/3'J 0
0
AT'
dy (47)
Combining Equations (36), (40), (46) and (47), the virtual work of internal balance forces is
ÖW = - 16a 6/3J 2 f L
Trpw cos ^ /. / b 0
g- a 1.0 0 D
0 0 cos ^ ft
c-1
0 0 0 11
0 0 0
k B C
e - a 0
1.0 0
0 cos ty ft
dy
(48)
Since ÖW = AQO Ö/3, in this case of correction for the control surface in- ternal aerodynamic balance, the incremental, two-dimsnsional, general- ized aerodynamic force to be added to Qj in Equation (42) is
i AQ^ = -irpw cos ^4 /
g,-a 1.0 0 b 0 0 cos $
ft
0 0 0
0 0 0
ABC
•1
g- a
1.0
0
0
0
COS 2/) ft
dy OL\
v\ (49)
■w*m T
k •
From Equations (42) and (49) we write the generalized aerodynamic forces, in 3x1 matrix form, as follows:
Q O!
Q ß -= CO
I 0 J
All A
A21 A
12 0] fa]
22 0 \ß\
0 OJ [y\
(generalized aerodynamic force, no aerodynamic balance)
(50)
[ 0 ' f
\*% 2
[ o ,
B
0 0 0' a
21 B22 0 i ß
0 0 oJ y.
(generalized aerodynamic force, aerodynamic balance Increment)
(51)
where, by expanding out Equations (42) and (49)
A = Tip cos *c/4 ./
Parent Surface
V1^) +(^ + Mj(^l+M a "W\ b a dy
A = Trp cos *c/4 /.
b cos 41. Control Surface
ft ß rj +Mß dy
H c j
r 4 \ a / Exp A01 = 7rp cos $ ,A l b cos ^, ,-
21 c/4 J„ , *i /C„ Control c / H
T l^-^l + T h\ b / a dy
Surface a /3
H
4 2 A = Trp cos 4> /A I b cos ^
22 c/4 r , '
c/ Exp.
Control Surface
■L /C c / H
Tß dy
c' 3
27
r^c H
B0, = irp cos 4> A / b cos ip. F__ K _£/ Exp.
21 r -'^ c/4 / Tfe BB /^C Aero. I c
A(c ■«M Bal.
a/ 3
-t B(c,a,k) dy
B22 = Trp cos ^/4 _/ b cos2 ^ FBB K Aero. Bal.
Exp. C(ctg,h) dy
Note that the basic surface expressions A21 and A22 have been modified by hinge moment correction factors/c„ \ //C„ \ , etc. in
order that these terms be consistent aerodynamic balance arrangement.
(^JEXP./^"^' t with the expressions foi expressions for the internal
The remaining portions of the analysis parallel the procedure treated in Paragraph 3.1, with changes in generalized coordinates as discussed in this paragraph. Note also that [I1] = [A] - [B].
28
4.0 DISCUSSION AND RESULTS
4.1 AILERON AND AILERON FLIGHT TAB
A schematic of the aileron and aileron flight tab system Is shown in Figure 1. A plan view of the wing, outer panel, aileron, and flight tab, showing the geometry of the analysis, is given in Figure 2, and the aero- dynamic balancing arrangement is shown in Figure 3.
Parameters
Table 1 lists the aerodynamic parameters required to evaluate the oscil- latory forces as defined in References 2, 3 and 4 and in Equation (22).
The inertia parameters are:
2 I = 4. 80598 lb.-in.-sec.
2 L = 0.03108 lb. -in. -sec. ö
2 St = -0.00086 lb. -sec. (nose heavy)
ö
I = 14.974 in.
2 AL = 0.10834 lb. -in. -sec. (see page 34 for definition)
2 J = 1.50690 lb.-in.-sec.
The uncoupled aileron rotation natural frequencies, a i ic parameter for this preliminary analysis, are: fß = 15, 20, and 30 cps.
Symmetric Analysts
For the purpose of a symmetric flutter analysis, the system is idealized as shown i'. Figure 4.
Since symmetric motion of the ailerons is contrary to the normal opera- tion of the system, the control stick Is assumed locked; hence the stick rotation freedom is not imposed in the symmetric analysis. It is further assumed that there is no mechanical gearing between flight tab and aileron. Note that the restraint of the power boost for the control system is represented herein by a simple spring.
29
\
I «I
.a
«
fe
lr
30
1/4 CHORD LINE
AILERON HINGE LINE
43.823
AILERON TAB HINGE LINE
Figure 2 Wing Outer Panel - Plan View
31
bOXCIIOHl)
Figure 3 Aileron Aerodynamic Balancing Arrangement
kc
Aircraft ^ of Symmetry, Point A, Figure I
Bellcrank Pivot
Figure 4 Idealization of Symmetric Aileron System
32
The degrees of freedom considered are
ß = Alleron rotation
ö = Alleron flight tab rotation, relative to the aileron
The potential energy of the system is
where
k = Linear spring restraint offered by control circuit, i.e., effective sprlr;g of half the control circuit from Point A to floating link at aileron hinge line
K = Rotational spring restraint offered by power actuator
r , r , r , r , r = Linkage arm lengths
(See Figure 4 for a schematic representation of k , K and the r's.)
Calculating the potential energy terms that are part of Lagrange's equa- tions of motion (Equations (1) and (2)) by taking partial derivatives of Equation (52).
^ = kcv-v>+v and
8U =k (-bfl+b6)
r, r . 13 2
4 r^ r^ 5 2 4
33
In matrix notation, the potential energy (spring) terms are,
b, k +K - b k 1 c p 4 c
-b k 4 c
bok
2 cJ = [s] {q}
and Equation (25), then, is
[V VI k* h. K
b k + K - b. k 1 c p 4 c
-b k ba k 4 c 2 c
11 12
V r L 21 22
(53) For the symmetric case, I, is the mass moment of the inertia of the tab about its hinge line I5 plus the effective mass moments of inertia Alg of half the control circuit (from Point A to tab) about the tab hinge line. The circuit members are assumed to move with the tab, not with the aileron nor independently, in this condition.
Upon expansion of the characteristic determinant of Equation (53), the following stability equation ib obtained:
Aß +Bß +C = 0 (54)
where A is real, and B and C are complex.
Parameters for the Symmetric Analysis
The linkage parameters are
r, =
r„ =
r„ =
r. =
r_ =
2.50 in.
2.26 in.
3.40 in.
2.50 in.
2.50 in.
34
The spring constants are
k = 5373 lb./in. c
K = 9109; 42,312; and 137,178 lb. -in. /rad., corresponding to f = 15, 20 and 30 cps, respectively.
K = 10,000 lb.-in./rad.
The value for Ic was calculated from design values for the aileron flight control tab system. The values for Kp were determined in using Equa- tion 27, for the various values of the uncoupled aileron frequency fo. The scaling constant K was assigned its value arbitrarily, for computing convenience.
Results
Tables 2 through 7 and Figures 5 through 10 show the effects of varying the aileron uncoupled frequency f^ and aerodynamic balance. Figure 11 shows a cross-plot of sea-level flutter velocity Vj versus fn for the sym- metric aileron condition.
Conclusions
In order to clear the flight envelope to 500 knots +15% (575 knots) at sea level, as required, examination of the tables and curves shows that the uncoupled tab frequency L must be made greater than indicated (51. 9 cps) either with or without aerodynamic balancing for the aileron. Since fg is not a parameter of the analysis, quantitative requirements for f^ are not available. The coupled, predominantly aileron mode (the lower- frequency branch) is stable for all f ^ values investigated. The symmetric flutter condition occurs in the coupled, predominantly tab mode (the higher-frequency branch), f*, particularly the value of kc, would strongly affect the flutter mode.
The uncoupled aileron frequency in has little effect on the flutter fre- quency, but the flutter velocity decreases with increasing fn. This effect is understandable in that the predominantly aileron mode coalesces to the predominantly tab mode with increasing %, thereby increasing the coupl- ing between the two modes. Increased coupling means a lower flutter velocity. Stating the above conclusions in another way, the (coupled) frequencies of the two branches should be separated more. Since the flutter mode consists predominantly of tab motion, the best way to secure increased separation is to increase fg, which in turn is best increased
35
by an Increased value of kc, the circuit stiffness. Further analysis should be made on calculated refinements to the circuit stiffness as the design develops and on the basis of tested values of uncoupled aileron and tab natural frequencies.
Aerodynamic balance of the aileron has little effect on the flutter frequency; however, the cases with balanced aileron (B^O) yield slightly higher flutter velocities, by about 30 knots, than the cases with unbalanced aileron (B=0) for the same fß value.
36
TABLE 1
AILERON - AILERON FLIGHT TAB AERODYNAMIC PARAMETERS
Aileron - Aileron Flight Tab Geometry:
Sta. B.L. b FBB No. in. in. c e' e" g* d f
1 102.40 55.120 0.626 0.559 0.498 0.708 0.00590 0.906 0.906 \
2 111.77 50. 742 0.602 0.533 0.473 0.682 0.00590 0,901 0.901
3 121.13 46.364 0.574 0.502 0.443 0.654 0.00589 0. 894 0.894
4i 130.50 41.986 0.539 0.464 0.407 0.619 0.00587 0.887 0.887 J
4« 130.50 41.986 0.539 0.464 0.407 0.619 0.00587 - " h
5 140.17 37.919 0.501 0.422 0.368 0.581 0.00579 - -
6 149.83 33.852 0.454 0.370 0.318 0.534 0. 00566 - - j V
7 159.50 29.785 0.393 0.303 0. 255 0.473 0. 00548 - -
8 169.16 25.718 0.314 0.216 0.172 0.394 0.00519 - -
9 178.83 21.652 0.204 0.130 0.130 0.284 0.0 - \J
Aileron &
Tab
* Aileron
Function C (c, g, k) evaluated for c = 0.467 (Avg.) and g = 0.547 Function D (c, d, k) evaluated for c = 0.467 (Avg.) and d = 0.897 (Avg.) * For g - c = 0.08
Aerodynamic Balance Arrangement:
Aileron, internal - simple nose overhang (curtain seal) Flight Tab, none - radius nose
Hinge Moment Corrections:
H
^^ =1.0 ;
37
TABLE 1 (Continued)
\ g / ExP' -in- \ t/Exp. =
h: ) t\ ) \ c/Exp. _ . \ t/Exp. =
\ 3
Pressure Recovery Factor:
K = 1.0
General:
Reference half-chord (b ) = 55.120 in.
cosip lt = 0.87114 c/4
cos «/) T = 0. 99871 c
cos i/* = 0. 99657
-6 2 -4 Altitude - Sea Level (p = 0.114626 x 10 lb. -sec - in. )
TABLE 2
SOLUTIONS OF STABILITY EQUATIONS
(Symmetric Analysis)
Plot: Figure 5
Uncoupled Natural Frequency, Aileron Rotation: lß= 15 cps
Spring Constants:
kc = 5373 lb./in.
K - 9109 Ib.-in./rad.
Aerodynamics: Basic Surface with Aerodynamic Balance (B f- 0)
1 fl cps Knots
.00 6.7 0.0
.05 6.5 5.6
.10 6.5 11.2
.15 6.6 16.9
.20 6.7 22.8
.50 7.7 65.7
.75 10.9 139.3 -
1.00 - -
Si
f2 cps
V2 Knots ^2
.000 53.9 0.0 .000
-. 032 53.8 46.0 -.004
-.064 53.8 92.0 -.008
-.097 53.8 138.0 -.011
-.131 53.8 184.0 -.014
-.433 53.5 457.7 -.002
1.280 54.2 695.5 .146
- 68.7 1174.1 .434
Vj = 463 knots
uncoupled Natural Frequency, Tab Rotation: f ö = 51.9 cps
TABLE 3
SOLUTIONS OF STABILITY EQUATIONS
(Symmetric Analysis)
Plot: Figure 6
Uncoupled Natural Frequency, Aileron Rotation: fa = 20 cps
Spring Constants:
kj; =5373 lb./in. K
p = 42,312 lb.-in./rad.
Aerodynamics: Basic Surface with Aerodynamic Balance (B ^ 0)
1 h Vi h V2 ko cps Knots Si cps Knots «2
.00 14.3 0.0 .000 54.1 0.0 .000
.05 14.0 12.0 -.032 53.9 46.1 -.004
.10 14.1 24,1 -.064 53.9 92.2 -.008
.15 14.2 36.4 -.097 53.9 138.3 -.011
.20 14.3 49.0 -.132 53.9 184.3 -.014
.50 16.6 142.2 -.443 53.4 456.7 .007
.75 23.9 306.5 -1.381 54.6 700.3 .184
1.00 - - - 70.1 1198.3 .442
Vf = 432 knots
Uncoupled Natural Frequency, Tab Rotation: f^ = 51.9 cps
TABLE 4
SOLUTIONS OF STABILITY EQUATIONS
(Symmetric Analysis)
Plot: Figure 7
Uncoupled Natural Frequency, Aileron Rotation: f« = 30 cps
Spring Constants:
k,, - 5373 lb. /in.
K = 137,178 Ib.-in./rad.
Aerodynamics: Basic Surface with Aerodynamic Balance (B t 0)
1 fl cps
Vl Knots gl
f2 cps
V2 Knots 62
.00 25.6 0.0 .000 54.5 0.0 .000
.05 25.0 21.4 -.032 54.4 46.5 -.004
.10 25.1 43.0 -.064 54.3 92.9 -.007
.15 25.4 65.0 -.098 54.3 139.2 -.010
.20 25.6 87.7 -.134 54.2 185.3 -.012
.50 30.3 259.4 -.485 53.2 454.7 .042
.75 44.7 572.7 -1.677 56.9 729.7 .278
1.00 a. _ _ 73.4 1255.3 .446
Vf = 356 knots
Uncoupled Natural Frequency, Tab Rotation: f6 = 51.9 cps
41
TABLE 5
SOLUTIONS OF STABILITY EQUATIONS
(Symmetric Analysis)
Plot: Figure 8
Uncoupled Natural Frequency, Aileron Rotation: fo = 15 cps
Spring Constants:
k= 5373 lb./in.
Kp=9i09 1b.-ln./raci.
Aerodynamics: Basic Surface without Aerodynamic Balance (B = 0)
.00
.05
.10
.15
.20
.50
.75
1.00
h cps
6.7
6.5
6.5
6.6
6.7
7.8
11.9
vl Knots
0.0
5.6
11.2
16.9
22.8
66.9
153.1
Si
.000
-.033
-.067
-.102
-.139
-.475
-1.634
f2 cps
53.9
53.8
53.8
53.8
53.8
53.4
54.7
73.1
Knots
0.0
46.0
92.0
138.0
184.0
456.6
701.2
1250.4
62
.000
-.004
-.008
-.011
-.014
.005
.196
.483
Vf = 434 knots
Uncoupled Natural Frequency, Tab Rotation: (6 = 51.9 cps
42
TABLE 6
SOLUTIONS OF STABILITY EQUATIONS
(Symmetric Analysis)
Plot: Figure 9
Uncoupled Natural Frequency, Aileron Rotation: f« = 20 cps
Spring Constants:
kc = 5373 lb./in. K= 42,312 lb.-in./rad.
Aerodynamics: Basic Surface without Aerodynamic Balance (B = 0)
1
ko
fl cps
Vl Knots gl
'2 cps V2
Knots «2
.00 14.3 0.0 .000 54.1 0.0 .000
.05 14.0 12.0 -.033 53.9 46.1 -.004
.10 14.1 24.0 -.067 53.9 92.2 -.008
.15 14.2 36.4 -.103 53.9 138.3 -.011
.20 14.3 49.0 -.140 53.9 184.2 -.014
.50 16.9 144.9 -.487 53.3 455.7 .015
.75 26.3 377.4 -1.773 55.3 709.8 .234
1.00 _ _ _ | 74.3 1269.9 .479
Vf = 404 knots
Uncoupled Natural Frequency, Tab Rotation: fg =51.9 cps
43
TABLE 7
SOLUTIONS OF STABILITY EQUATIONS
(Symmetric Analysis) ~y
Plot: Figure 10
Uncoupled Natural Frequency, Aileron Rotation; f = 30 cps
Spring Constants:
k^ = 5373 lb./in.
K = 137,178 Ib.-in./rad.
Aerodynamics: Basic Surface without Aerodynamic Balance (B = 0)
1 k o
h i cps Knots h cps
V2 Knots 62
.00 25.6 0.0 .000 54.5 0.0 .000
.05 25.0 21.4 -.034 54.4 46.5 -.004
.10 25.1 43.0 -.068 54.3 92.9 -.007
.15 25.4 65.0 -.104 54.3 139.2 -.010
.20 25.7 87.8 -.142 54.2 185.3 -.012
.50 30.9 264.4 -.535 53.1 454.4 .053
.75 48.9 627.7 -2.127 58.1 745.7 .313
1.00 — — _ { 76.9 1315.5 .461
I»
Vf = 320 knots
Uncoupled Natural Frequency, Tab Rotation: f ^ = 51.9 cps
U-.
bO
Ü
< p
0.20
0.15
0.10
0.05
0-
-0.05
.. .j. ..
-0.10 I I ■
-0.15
-0.20
l
: ....
.
. ..
~r-
.:::;..l... . . . r ...
■:
■ 1 i 1 '
...i...t..,|-.;.... .
..: t
. ■.: :: IW .!. :
... ■
. ;
,
1 ... 1..: :. 1 . ■
.... — T;I;:: ■ .■!:: ; vi:
::*• •••• .... ■
■
-^-.
' •'; i
...
.. i ... ... ).
; ■•■■1
■
■
i :j/
■ • i: ' ■
i;
.. I::.
.. i
. -i. . , . s .. t
F '
■*■ rrr TTT ....
2 ; ■ ■
.::„j;;.: :"M.-::
■ ■ t
...:j ...
. ■ : i. ■ :M;::
■ ■ ■
.... I
1 . ! ., • ■
. . . ::r •■:: •":
. !•.••::
rrrr :rr:- :' ;■ i.:.
. ,. (. •.
v. .! . . r.i:. r-;:- .:..._ ■•;; !:;:
■.:"V.--: ,'**■* • H^Pi ■ .1 .;
. • «-«M • »V*.
.:;; .: . : ■:; 1:: ■ . . . . l . • , .
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lv ■■■
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:;; 1000
Figure 5 g-V and f-V Plots, Symmetrie Aileron, fß= 15 eps, B ^ 0
45
I p*20
i ;
i ; 0.15
—; o.io
... be 0.05 i
' ü : - HH - 0
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Figure 6 g-V and f-V Plots, Symmetric Aileron, io -= 20 cps, B / 0
46
>
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; 600 VELOCITY - KNOTS i ; 1 fj;; n^luHl ^j :1 L._J ... L.-.J>.-.J. ... L JLÜi;
:; 1000
Figure 7 g-V and f-V Plots, Symmetric Aileron, io = 30 cps, B ^ 0
47
0.20
■ . 1 : .1
■■■'t*"'.' 1
. - » ■ »* ■ *-fcl-»l
l..>
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L.._L„'J .
: 1000
Figure 8 g-V and f-V Plots, Symmetric Aileron, fo = 15 ops, B = 0
48
U.£U
; 1000
Figure 9 g-V and f-V Plots, Symmetric Alleron, (ß= 20 cps, B = 0
49
4 -..MiW-rtH >"•♦'■*'"-' m^wv^w ■ ...Vi^MrlU". ■ ••-•^«•'•:' . . : «««««ßm«^fc-> -v *:.\r''xiTim***'-'r.. i&tTjfrw** i#, wüui
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Figure 10 g-V and f-V Plots, Symmetric Aileron, fß = 30 cps, B * 0
50
1-fe*. t* irt^^hj- '■'>«i"J.
I—I < Q W u
P w Ü
PQ _
o o -H- II PQ PQ 0<J
o o
o o
o 6? 9 ^ m Q
o o
s w >
a fc
o o <N
o o
0)
£
o o CO
o
^ ft
51
~. .—...
Antisymmetric «Xnalysls
For the purpose of an antisymmetric flutter analysis, the system is idealized as shown in Figure 12. %
kc VNAA-
Ail. HL
Bellcrank Pivot
Figure 12 Idealization of Antisymmetric Aileron System
The degrees of freedom considered are as follows:
ß = Alleron rotation
6 = Alleron flight tab rotation, relative to the aileron
y - Control stick rotation
It is still assumed that there Is no mechanical gearing between flight tab and aileron and that the restraint of the power boost for the control sys- tem can be represented by a simple spring.
The potential energy of the system is
it 4
59
where
k = Linear spring restraint offered by control circuit; i.e., the effective spring of half the control circuit from control sticks to floating link at aileron hinge line
K = Rotational spring restraint offered by power actuator
rr V '^S' V r5' r23 = Llnka8e arm lengths
(See Figure 12 for a schematic representation of k , K and the r's)
Taking partial derivative of Equation (55),
w' kcV-V +v>+V
W~ kc<-a4^+a2*-a61')
O TT
= k (a /3-a 6 + a. y) dy c l 5 6 3Yf
where
2 a = r (= b of the symmetrical case, page 33)
r r
2 4
a = r * 3 23
r r 1 3 2 / K V a. = r (= b )
4 ro rA 5 4
5 5 23
""I r3 a = — r r 6 r2 r4 5 23
S3
^H -rj. -fW-*-
In matrix notation, then, thr potential energy (spring) terms in Lagrange's equations of mohon (Equations (1), (2), and (3)) are
[a, k +K | 1 c p -a k 4 c
a k 5 c '^1
4 c aok
2 c -a k
6 c 6
1 ack
L 5 c -aflk
6 c ak
3 c_ y
= [8] {q}
and Equation (25) is
P^ 0
Pöß h 0 0
-n K
a, k +K -a k a^k 1 c p 4 c 5 c
-a k a„k -a k 4c 2c 6c
a k -a„k a k 5 c 6 c 3 c
"■
V V 11 12
p ß ol
+ r i1
21 22 p 6 = 0
0 0 p y 0 _J '"■ '— "■
(56)
Upon expansion of the characteristic determinant of Equation (56), be- cause of relationships between [S] elements in terms of the r's ([S] is singular), the following stability equation is obtained:
Aß + Bß +C = 0
where A is real, and B and C are complex.
(57)
Parameters for the Antisymmetric Analysis
The linkage parameters, r through r , are the same as given previously for the symmetric case, page 34.
r23 = 3.20 in.
The spring constants are:
k =911 lb./in. c
K = 39,496; 72,699; and 167, 565 lb.-in./rad. corresponding to p f = 15, 20 and 30 cps, respectively.
K = 10,000 lb.-In./rad.
54
- 'JRJ^ ■ .-*mm
The value for k. was calculated from design values for the aileron-flight tab control system. The values for Kp were determined, using Equation 27, for the various values of the uncoupled allerem frequency fo. The scaling constant K was assigned its value arbitrarily, for computing convenience.
Results
Tables 8 through 13 and Figures 13 through 18 show the effects of varying the aileron uncoupled frequency f. and aerodynamic balance.
Conclusions
Examination of the analysis results show that antisymmetric aileron system flutter will not occur over the range of fo and IAQ values in- vestigated, either with or without aerodynamic balance for the ailerons.
55
TABLE 8
SOLUTIONS OF STABILITY EQUATIONS
(Antisymmetric Analysis)
Plot: Figure 13
Uncoupled Natural Frequency, Aileron Rotation: f^ = 15 cps
Spring Constants:
kc = 911 lb./in.
K= 39,496 lb.-in./rad.
Aerodynamics: Basic Surface with Aerodynamic Balance (B ^ 0)
1
*0
fl cps
Vl Knots Si
f2 cps
V2 Knots ^2
.00 13.9 0.0 .000 103.8 0.0 .000
.05 13.6 11.6 -.031 102.6 87.7 -.029
.10 13.6 23.3 -.061 103.4 176.9 -.060
.15 13.7 35.1 -.093 104.9 269.0 -.094
.20 13.8 47.1 -.126 107.0 365.9 -.133
.50 15.2 130.2 -.377 152.7 1305.6 -.848
.75 18.6 239.2 -.822 - - -
1.00 35.7 610.0 -3.822 _ mm _
Uncoupled Natural Frequency, Tab Rotation: fß = 102.5 cps
56
TABLE 9
SOLUTIONS OF STABILITY EQUATIONS
(Antisymmetric Analysis)
Plot: Figure 14
Uncoupled Natural Frequency, Aileron Rotation: ia = 20 cps
Spring Constants
k =911 lb./in. u K =72,699 Ib.-in./rad.
Aerodynamics: Basic Surface With Aerodynamic Balance (B ^ 0)
1 fi cps
Vl Knots Si cps
V2 Knots h
.00 19.2 0.0 .000 103.8 0.0 .000
.05 18.7 16.0 -.031 102.6 87.7 -.029
.10 18.7 32.0 -.061 103.5 176.9 -.060
.15 18.8 48.3 -.093 104.9 269.0 -.094
.20 19.0 64.9 -.126 107.0 365.9 -.132
.50 21.0 179.6 -.377 152.5 1303.8 -.848
.75 25.8 331.0 -.818 - «■ -
1.00 52.7 901.8 -4.198 .. . _
Uncoupled Natural Frequency, Tab Rotation: fg = 102.5 cps
57
TABLE 10
SOLUTIONS OF STABILITY EQUATIONS
(Antisymmetric Analysis)
Plot: Figure 15
Uncoupled Natural Frequency, Aileron Rotation: f^ = 30 cps
Spring Constants:
k =911 lb./in. c
K = 167,565 lb.-in./rad. P
Aerodynamics: Basic Surface with Aerodynamic Balance (B ^ 0)
1
ko cps vi
Knots ßl f2 cps
V2 Knots S2
.00 29.4 0.0 .000 103.8 0.0 .000
.05 28.6 24.5 -.031 102.7 87.7 -.029
.10 28.7 49.1 -.062 103.5 176.9 -.060
.15 28.8 74.1 -.094 104.9 269.0 -.093
.20 29.1 99.6 -.127 107.0 365.8 -.131
.50 32.3 276.5 -.377 151.9 1298.4 -.847
.75 40.1 513.7 -.799 - ■a
1.00 103.7 1772.9 -5.281 _ _ mm
Uncoupled Natural Frequency, Tab Rotation: f^ = 102.5 cps
58
TABLE 11
SOLUTIONS OF STABILITY EQUATIONS
(Antisymmetric Analysis)
Plot: Figure 16
Uncoupled Natural Frequency, Aileron Rotation: (ß = 15 cps
Spring Constants:
k =911 lb./in. c
K =39,496 lb.-in/rad. P
Aerodynamics: Basic Surface without Aerodynamic Balance (B = 0)
1 ko cps
Vl Knots Si
f2 cps Knots 82
.00 13.9 0.0 .000 103.8 0.0 .000
.05 13.5 11.6 -.032 102.6 87.7 -.029
.10 13.6 23.2 -.065 103.4 176.9 -.060
.15 13.7 35.1 -.098 104.9 269.0 -.094
.20 13.8 47.2 -.134 107.0 365.8 -.132
.50 15.5 132.3 -.414 151.4 1294.1 -.830
.75 19.8 254.4 -.989 - - -
1.00 78.4 1340.0 -19.770 - — _
Uncoupled Natural Frequency, Tab Rotation: £5 102.5 cps
59
"!■*»«* ' ■ ..^..-^•^•»i
TABLE 12
SOLUTIONS OF STABILITY EQUATIONS
(Antisymmetric Analysis)
Plot: Figure 17
Uncoupled Natural Frequency, Aileron Rotation: fyj = 20 cps
Spring Constants:
k =911 lb./in. c
K =72,699 lb.-in./rad. P
Aerodynamics: Basic surface without Aerodynamic Balance (B = 0)
1 k o
1 cps
vi Knots gl
f2 cps
V2 Knots h
.00 19.2 0.0 .000 103.8 0.0 .000
.05 18.7 15.9 -.032 102.6 87.7 -.029
.10 18.7 32.0 -.065 103.4 176.9 -.060
.15 18.8 48.3 -. 099 104.9 269.0 -.094
.20 19.0 65.0 -.134 107.0 365.8 -.132
.50 21.4 182.6 -.414 151.1 1292.1 -.829
.75 27.5 352.6 -.987 - - -
1.00 259. G 4439.2 -110.501 — _ _
Uncoupled Natural Frequency, Tab Rotation: f^ = 102.5 cps
60
km mm.
TABLE 13
SOLUTIONS OF STABILITY EQUATIONS
(Antisymmetric Analysis)
Plot: Figure 18
Uncoupled Natural Frequency, Aileron Rotation: (o = 30 cps
Spring Constants:
k =911 lb./in. c
K = 167,565 Ib.-in./rad. P
Aerodynamics: Basic Surface without Aerodynamic Balance (B = 0)
1 k o
fl cps
Vl Knots gl
f2 cps
V2 Knots g2
.00 29.4 0.0 .000 103.8 0.0 .000
.05 28.6 24.5 -.033 102.7 87.8 -.029
.10 28.7 49.1 -.066 103.5 176.9 -.060
.15 28.9 74.1 -.100 104.9 268.9 -.093
.20 29.1 99.7 -.135 106.9 365.6 -.131
.50 32.9 281.2 -.415 150.4 1286.0 -.828
.75 42.9 550.2 -.976 - - -
1.00 415.5 7105.2 -34.596 1 - - -
Uncoupled Natural Frequency, Tab Rotation: fg = 102.5 cps
61
-.^i
0.20
1000
62
Figure 13 g-V and f-V Plots, Antisymmetric Aileron, fg = 15 cps, B ?* 0
-nr ̂..^-nWhii liiiii |> gg
kl. llfc1 ■
10.20
1000
Figure 14 g-V and f-V Plots, Antisymmetric Aileron, fö= 20 cps, B ^ 0
63
10.20
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to 0.05 i '
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800
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1000
Figure 15 g-V and f-V Plots, Antisymmetric Aileron, fg= 30 cps, B^ 0
64
[::;■■;" 10.20 j .
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V
1 .
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...u., VELOCITY - KNOTS
1000
Figure 16 g-V and f-V Plots, Antisymmetric Aileron, fo- 15 cps, B = 0
65
10.20 I ;::::.H,.
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1" VELOCITY - KNOTS T i i . i -i jl
800 m
T:
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1000
Figure 17 g-V and f-V Plots, Antisymmetric Aileron, fo= 20 cps, B = 0
66
(kk ii#.
I . .. 4 <
bfi
10.20
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::::i:: ; ..
;■!:"•
.:■.!■:.'
■ r
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^
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hnr • . , . . t . .
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:|r :' l^ik. :,-:i :: :.:: t: ::
■''; t':;'
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r::;U--. :*.'!.:.
.;:!:: '
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.;;.!.■ .
'.:. 1:;::
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, ...•.•■
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:.: i::::
l.^i^LA. — LIJ _ii^— :;;:!■: •.: ; t 1 ■
Figure 18 g-V and f-V Plots, Antisymmetric Aileron, £j= 30 cps, B = 0
67
*J
4.2 RUDDER AND RUDDER TRIM TAB
A schematic of the rudder and rudder trim tab system is shown in Figure 19. A plan view of the vertical tail, rudder and trim tab is shown in Figure 20, and the aerodynamic balancing arrangement is shown in Figure 21.
Analysis
For purposes of a flutter analysis, the system is idealized as shown in Figure 22. For the trim tab system at hand, no mechanical gearing exists between the rudder and tab; i. e., n = 0(n is a gear ratio, trim tab rotation to rudder rotation 6/ ß).
ß = Rudder rotation
Ö = Rudder trim tab rotation, relative to the rudder
y = Control pedal rotation
The potential energy of the system is
where
k = Linear spring restraint offered by control circuit, i. e. the effective spring of the complete control circuit from control pedal to rudder quadrant
K = Rotational spring restraint offered by trim tab actuator
r , r = Linkage arm lengths 1 8
(See Figure 22 for a schematic representation of k , K,, r and c A 1
v> Calculating the potential energy terms that are part of Lagrange's equations of motion (Equations (1), (2) and (3)), by taking partial derivatives of Equation (58),
i
i
66
9U äl = ko<a/-a2T>
If = KAa
|i = k0(V+a3V»
where
a. = r
a„ = 1 8
a„ = r 8
In matrix notation, the potential energy (spring) terms are
ra1 k 1 c
0 -a2V 'ß
0 KA 0 6
Kkc 0 a3koJ 1 .y
[S] {q}
and Equation (25) is
ß ßö
P I
0 0
0
0
JJ K
a,k 1 c
0
0
-aftk 0 2 c
-a k 2 c
0
a3kcJ
i1 r 11 12
01 'ß' 0]
i* r 21 22
0 5 = 0
0 0 oj .YJ .oj (59)
In the case at hand, J is the effective mass moment of inertia of the con- trol circuit and pedal about the pedal pivot axis.
Upon expansion of the characteristic determinant of Equation (59), be- cause of relationships between [S] elements in terms of the r's ([S] is singular), the following stability equation is obtained:
A«2 + Bß +C =0
where A is real, and B raid C are complex.
69
^■"i*i*^jfc(.j .,-.-
^C
v^
A
Rudder
Rudder Trim Tib
Trim Tail Actuator
Figure 19 Schematic of Rudder System
VI'AM IIINtlK LINK Wt HIinilKKCIIOKO
Figure 20 Vertical Tall - Plan View
70
■to...... . .Jbb-JMw .»>
50% CHOrtD
Figure 21 Rudder Aerodynamic Balancing Arrangement
|/ 8
AW
ß
>
Figure 22 Idealization of Rudder System
K
-^
A
71
..».a
Parameters
Table 14 lists the aerodynamic parameters required to evaluate the oscil- latory forces as defined in References 2, 3 and 4 and in Equation (22).
The inertia parameters are
2 I = 2. 31997 lb. -in. -sec.
2 L = 0. 02604 lb. -in. -sec. o
2 S = 0. 00596 lb. -sec. (Tail heavy)
i =11.902 in. V
2 J =0. 95234 1b.-in.-sec.
The uncoupled rudder trim tab rotation natural frequencies, a basic parameter for this preliminary analysis, are fg = 20, 40 and 60 cps.
The linkage parameters are:
r =5.5 in.
r0 =9.6 in. o
The spring constants are:
k =357 lb./in. c
K =411, 1645, and 3702 lb.-in./rad. corresponding to f- = 20, 40 and 60 cps, respectively.
K = 10, 000 1b.-in./rad.
The value for kc was calculated from design values for the rudder-trim tab system. The values for K^ were determined using Equation 28, for the various values of uncoupled trim tab frequency fg. The scaling con- stant K was assigned its value arbitrarily, for computing convenience.
72
ros /
it- ■
Results
Tables 15 to 20 and Figures 23 to 28 show the effects of varying the rudder trim tab uncoupled frequency fg and aerodynamic balance. Fig- ure 29 shows a cross-plot of sea-level flutter velocity Vf versus fg.
Conclusions
In order to clear the flight envelope to 500 knots + 15% (575 knots) at sea level, as required, examination of the tables and curves shows that the uncoupled trim tab frequency fg must be at least 59 cps for the aero- dynamlcally unbalanced rudder (ß = 0) and at least 50 cps for the aero- dynamically balanced rudder (/3 ^0). Thus an increased K^ value, trim tab actuator stiffness, is indicated. The coupled, predominantly rudder mode (the lower-frequency branch) is stable for all ^ values investigated. The flutter condition occurs in the coupled, predominantly trim tab mode (the higher-frequency branch). ^, and particularly the value of K^, as expected, strongly influences both the flutter velocity and frequency. They both increase with increasing ^. Further analysis should be made on calculated refinements to the circuit stiffness as the design develops and on the basis of tested values of uncoupled rudder and trim tab natural frequencies.
Aerodynamic balance of the rudder has considerable effect on the flutter velocity. Flutter velocities are substantially greater for the aero- dynamically balanced rudder (0^0) than for the unbalanced one {ß =0), for the same ^ value. Figure 29 shows a quantitative comparison.
73
TABLE 14
74
RUDDER - RUDDER TRIM TAB AERODYNAMIC PARAMETERS v»
Rudder - Rudder Trim Tab Geometry:
Sta. W.L. ! b
No. in. in. c e' e" g FBB d f '
1 118.63 50.449 0.640 0.579 0.511 0 690 0.00649 0.910 0.910
2 126.66 48.294 0.640 0.579 0.511 0 690 0.00652 0.910 0.910
3 134.69 46.139 0.640 0.580 0.510 0 690 0.00658 0.910 0.910
4I 142.72 43 984 0.640 0.580 0.510 0 690 0.00662 0.910 0 910
4o 142.72 43.984 0.640 0.580 0.510 0 690 0.00662 - -
5 152.61 41 329 0.640 0 581 0.510 0.690 0.00670 - -
6 162.50 38.675 0.640 0.582 0.510 0.690 0.00679 - -
7 172.39 36 021 0.640 0.582 0.509 0.690 0.00687 " l
8 182.28 33.361 0.640 0 583 0.509 0.690 0.00698 - -
Rudder &
Tab
' Rudder
Aerodynamic Balance Arrangement: i
Rudder, internal - simple nose overhang (curtain seal) Trim Tab, none - radius nose
Hinge Moment Corrections:
c/ Exp. = 1.0
c/ Exp. = 1.0
t/ Exp.
H
H
H.
= 1.0
t / 3
t / Exp. = 1.0
■i
TABLE 14 (Continued)
'\ c/Exp. =1<0 \t/Exp.=1>0
^CH \ ' ' /ACH
c/3 \ t/3
Pressure Recovery Factor:
K= 1.0
General:
Reference half chord (b0) = 51,960 in.
cos ip ,= 0.865999 c/4
cos 4>r = 0.965086 c
cos 4), = 0.980775
-6 „ 2 -4 Altitude - sea level (p = 0.114626 x 10 lb-sec. -in. )
75
TABLE 15
SOLUTIONS OF STABILITY EQUATIONS
Plot: Figure 23
Uncoupled Natural Frequency, Trim Tab Rotation: fß = 20 cps
Spring Constants:
k = 357 lb./in. c
KA =411 Ib.-in./rad A
Aerodynamics: Basic Surface with Aerodynamic Balance (B ^ 0)
1 k
0
fi cps
Vl Knots gl
£2 cps
V2 Knots g2
.00 21.3 0.0 .000 32.1 0.0 .000
.20 20.6 34.1 -.100 22.2 71.4 -.039
.40 11.3 72.6 -.238 21.6 139.4 -.028
.60 12.8 123.4 -.521 20.9 202.5 .140
.80 15.3 197.8 -1.166 22.9 295.2 .603
1.00 20.7 334.4 -2.827 33.0 532.3 2.039
1.20 97.5 1885.6 -75.178 _ _ *.
V = 170 knots
Uncoupled Natural Frequency, Rudder Rotation: fo = 10.86 cps
76
TABLE 16
SOLUTIONS OF STABILITY EQUATIONS
Plot: Figure 24
Uncoupled Natural Frequency, Trim Tab Rotation: f0 = 40 cps
Spring Constants:
k =357 lb./in. c
KA = 1645 Ib.-in/rad. A
Aerodynamics: Basic Surface with Aerodynamic Balance (B ^ 0)
1 k
0 cps
vi Knots gl
f2 cps
V2 Knots h
.00 31.1 0.0 .000 44.0 0.0 .000
.20 10.7 34.5 -.092 43.7 140.9 -.047
.40 11.5 71.4 -.197 43.8 282.6 -.067
.60 11.8 113.8 -.336 43.7 423.0 -.017
.80 13.0 167.8 -.563 43.6 562.1 .196
1.00 15.3 246.6 -1.018 46.5 749.3 .806
1.20 20.1 388.6 -2.211 75.8 1467.2 4.394
1.40 42.9 967.3 -11.996 — — -
V = 446 knots
Uncoupled Natural Frequency, Rudder Rotation: f^ = 10.86 cps
77
TABLE 17
SOLUTIONS OF STABILITY EQUATIONS
Plot: Figure 25
Uncoupled Natural Frequency, Trim Tab Rotation: f^ = 60 cps
Spring Constants:
k =357 lb./in. c
K = 3702 Ib.-in./rad. A
Aerodynamics: Basic Surface with Aerodynamic Balance (B ^ 0)
1
k 0
fi cps Knots gl
f2
cps V2
Knots g2
.00 31.4 0.0 .000 65.5 0.0 .000
.20 10.7 34.6 -. 090 65.4 210.9 -.048
.40 11.0 71.2 -. 191 65.9 424.8 -.073
.60 11.6 112.5 -.318 66.2 640.4 -.034
.80 12.6 163.0 -.503 66.2 853.7 .148
1.00 14.4 232.7 -.831 08.0 1095.7 .652
1.20 18.0 348.7 -1.591 88.5 1712.0 2.655
1.40 29.2 650.4 -4.955 _ _ —
V - 700 knots
Uncoupled Natural Frequency, Rudder Rotation: f,^ = 10.86 cps
78
L
TABLE 18
SOLUTIONS OF STABILITY EQUATIONS
Plot: Figure 2G
Uncoupled Natural Frequency, Trim Tab Rotation: [5 = 20 cps
Spring Constants:
k =357 lb./in. c
K =411 Ib.-in./rad. A
Aerodynamics: Basic Surface without Aerodynamic Balance (B = 0)
1
k 0
f 1
cps vi
Knots h f 2
cps V2
Knots g2
.00 21.3 0.0 .000 32.1 0.0 .000
.20 10.Ü 34.2 -.112 22.1 71.3 -.037
.40 11.5 74.1 -.280 21.4 138.0 -.003
.00 13.5 130.0 -.093 20.9 202.1 .277
.80 17.2 221.4 -1.721 25.1 323.3 1.046
1.00 30.0 483.8 -0.857 GO.2 909.7 9.019
1.20 _ _ _ _ .. _
V - 138 knots
Uncoupled Natural Frequency, Rudder Rotation: f^ = 10.80 cps
79
. . J
V
1
TABLE 19
SOLUTIONS OF STABILITY EQUATIONS
Plot: Figure 27
Uncoupled Natural Frequency, Trim Tab Rotation: £5 = 40 cps
Spring Constants:
k - 357 lb. /in. c
KA = 1645 Ib.-in./rad. A
Aerodynamics: Basic Surface without Aerodynamic Balance (B = 0)
1 k 0
fi cps
vi Knots gl
f2 cps
V2 Knots g2
.00 31.1 0.0 .000 44.0 0.0 .000
.20 10.7 34.6 -.104 43.6 140.7 -.045
.40 11.3 72.7 -.229 43.4 279.9 -.051
.60 12.4 119.6 -.422 42.4 409.9 .064
.80 14.6 188.4 -.827 41.7 538.1 .489
1.00 19.8 319.8 -2.046 54.1 871.9 2.234
1.20 64.8 1252.9 -27.060 _ _ _
V = 379 knots
Uncoupled Natural Frequency, Rudder Rotation: fo = 10.86 cps
80
t-
TABLE 20
SOLUTIONS OF STABILITY EQUATIONS
Plot: Figure 28
Uncoupled Natural Frequency, Trim Tab Rotation: f5 = 60 cps
Spring Constants:
k = 357 lb. /in. c
K = 3702 Ib.-in./rad. A
Aerodynamics: Basic Surface without Aerodynamic Balance (B = 0)
1 k
0
f 1
cps V
Knots gl
S2 cps
v2
Knots g2
.00 31.4 0.0 .000 65.5 0.0 .000
.20 10.8 34.7 -.102 65.3 210.6 -.047
.40 11.2 72.5 -.223 65.3 421.0 -.057
.60 12.2 117.9 -.394 64.1 620.4 .040
.80 14.1 181.4 -.711 62.2 801.9 .401
1.00 18.4 296.2 -1.567 70.9 1142.5 1.690
1.20 40.4 781.8 -9.309 _ _ _
V = 587 knots
Uncoupled Natural Frequency, Rudder Rotation: fo = 10. 86 cps
81
. i
0.20
bß I
dl
■ ■ i ■ ■
0.15
0.10
05
...0-
i ■
i — 0 -0.05
t
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-0.15
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1000
Figure 23 g-V and f-V Plots, Rudder, f^ = 20 cps. B ^ 0
0.20
800 ; 1000
I i I I I - * - - T • - - M
Figure 24 g-V and f-V Plots, Rudder, f. = 40 cps, B ^ 0
T
1000
Figure 25 g-V and f-V Plots, Rudder, f. = 60 ops, B ^ 0
84
*■!.-. I
0.20
' 0.15 i
i
i 0.10
hr 0-05
I
Ü Z 0 l—t
tu g ..
Q -0.05
i • : 0.10
-0,15
-0.20
-i -JL. ..
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t
1 1
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& t.... • Of
i i s ;.-.,
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r......t
-40-
30 -
20-
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1
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I 400 ; VELOCITY - KNOTS
j; ..I ■: . I:. ■!, ;J...i -i-.J.
rfrrr-
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E.
::v.
800
-—i. I; ,
1000
—i-
Figure 26 g-V and f-V Plots. Rudder, f. = 20 cps, B = 0
85
■xssm
i ■ . j
- , 0.20 ' 1 .... ;
• . .., ■. \ ...... . i
........
i
' !', ■ ,
• - ; ■ • ■
■*'""'
!. I .
,_rj...... :.; r::
,.r.;.:..;
: 1 • ...„..,_.: oao
- -;- bo' 0.05
—L-~-
L. ■, :1 :•■
! / i :
i : : :•: 1 --
■ t:.;:
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: ;.; 1: ..: ^ ,...,.. t . . .
l—I -J-0.20 Li-Lii; .i..: :; ; . ■ i-jli;;ih:i;'i.:;
1000
tr
Figure 27 g-V and f-V Plots, Rudder, f. = 40 cps, B = 0
86
T
0.20
0.15
0.10
be 0.05
M
■ s 2 -0.
0
05
i : i -0, 10
i i
-0. 15
i > -0. ,20
I......
1000
Figure 28 g-V and f-V Plots, Rudder, f^ = 60 ops, B = 0
87
m~%.
ff
ff g
PS w Q u W K
3 2 2 1 | o o if- ll PQ « O <1
#
o o
■o o CO
s H O
n W
o o
O o
T3
a i
«a CO
s
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OS >
OS M
(I)
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o «5
O o
J0 P. o
^
88
^
4.3 HORIZONTAL STABILIZER AND ELEVATOR
A schematic of the horizontal stabilizer and elevator system is shown in Figure 30. A plan view of the horizontal stabilizer and elevator is shown in Figure 31, and the aerodynamic balancing arrangement is shown in Figure 32.
Analysis
For purposes of a flutter analysis, the system is idealized as shown in Figure 33. Only the symmetric condition is treated here. Examination of the system shows that for the antisymmetric condition, a node exists at the centerline of symmetry. Thus, antisymmetric rotational motion of a representative station of the elevator and horizontal stabilizer are those of torsional cantilevers. The spring restraint is that of the elevator inter- connect torque tube and the torque box material for these two inertial ele- ments. There is no motion of the elevator control system since the ele- vator horn is located on the node (physically it is very near the aircraft centerline of symmetry at the vertical tail tip). Thus, the antisymmetric elevator system is extremely stiff relative to the symmetric one, while the Inertias of the surfaces remain the same. For an antisymmetric analysis, the generalized coordinate Y, control stick rotation, would cease to be a consideration, and control circuit stiffness as well as hori- zontal stabilizer trim actuator stiffness (the actuator Is also located at the node) would cease to be elements of the analysis; there would be no coupling to the control system. On the basis of these observations, the antisymmetric elevator flutter condition Is clearly not critical In com- parison to the far softer symmetric case.
The degrees of freedom considered for the symmetric analysis are:
Q! = Horizontal stabilizer rotation
ß = Elevator rotation, relative to horizontal stabilizer
7 = Control stick rotation
The potential energy of the system is
^iW-V^ +TKHa2 (61)
89
awrgg— m**
where k = Linear spring restraint offered by control circuit, i. e., the effective spring of half the control circuit from control stick to elevator horn \*
K = Rotational spring restraint offered by horizontal stabilizer trim actuator, half of the actual spring, due to symmetry
r , r = Linkage arm lengths 18
(See Figure 33 for a schematic representation of k , KH, r1 and r .)
Calculating the potential energy terms that are part of Lagrange's equations of motion (Equations (43), (44) and (45)) by taking partial de- rivatives of Equation (61),
au - ^(a^^y)
au ay
kcV+V>
where a. = r 1
a^ = r 8
a = r r 3 1 8
In matrix notation, the potential energy (spring) terms, then, are
KH 0 0
0 a,k a k 1 c 3 c
0 a k aftk 3 c 2 c
a
y\
[S] |q|
90
i
and Equation (25), with the changes in generalized coordinates discussed on page 18, becomes
a p
aß 0'
\ 0 0 " 'vu v en
12 a' 0
?aß lß 0
K 0 ak
1 c a0k
3 c +
■21 22 ß = 0
0 0 v . 0 3 c
ak 2 c J . 0 o oj .y. 0,
(62)
In the case at hand, because of symmetry, J0 is the effective mass mo- ment of inertia of half the control circuit and control stick about the con- trol stick axis of rotation.
Upon expansion of the characteristic determinant of Equation (62), be- cause of relationships between [S ] elements in terms of the r's ([S ] is singular), the following stability equation is obtained:
2 Aß + Bß + C = 0 (63)
where A is real, and B and C are complex.
Parameters
Table 21 lists the aerodynamic parameters required to evaluate the oscil- latory forces as defined in References 2 and 4 and in Equations (50) and (51).
The inertia parameters are:
2 I = 42.1394 lb. -in. -sec. (half horizontal stabilizer)
2 I = 0. 8906 lb. -in. -sec. (half elevator)
2 S = -0.0153 lb. -sec. (half elevator) - (nose heavy)
l = 21.09 in.
2 J = 1.4404 lb.-in.-sec.
o
The uncoupled horizontal stabilizer rotation natural frequencies, basic parameters for this preliminary analysis, are f = 20, 40 and 60 cps.
91
The linkage parameters are:
r = 4.0 in.
r = 5.125 in. o
The spring constants are:
k = 1145 lb./in. (half system)
K = 665,400; 2,661,800 and 5,988,900 lb. -in. /rad. correspond- ing to fa =20, 40 and 60 cps, respectively.
K = 10, 000 lb.-in./rad.
The value for ICQ was calculated from design values for the elevator sys- tem. The values of KJJ were determined for the various values of un- coupled horizontal tail frequency f^. The scaling constant K was assigned its value aribitrarily, for computing convenience.
Results
Tables 22 through 27 and Figures 34 through 39 show the effects of vary- ing the horizontal stabilizer uncoupled frequency fa and aerodynamic balance.
Conclusions
Examination of the analysis results shows that elevator system flutter will not occur over the range of fo and l/k0 values investigated, either with or without aerodynamic balance for the elevator.
e **
92
Elevitor
Figure 30 Schematic of Elevator System
MOKI/ONTAI. NTAIIIU/Mt IMVdl AXIS
1/4 mom» UNI
KI.KVATOK IIINliK LINK (/Km.HWKKP)
uu.iio
«6. ab
79.1U
4.7«
Figure 31 Horizontal Tail - Plan View
93
■saw
Mit CllOltl)
a
Figure 32 Elevator Aerodynamic Balancing Arrangement
A h-, KH T^
\
/
() ^2 (r0 = rj
— k
\
Figure 33 Idealization of Elevator System t 94
I 4.
TABLE 21
HORIZONTAL STABILIZER - ELEVATOR AERODYNAMIC PARAMETERS
Horizontal Stabilizer - Elevator Geometry:
Sta. B.L. b g a No. in. in. c e' e" g
FBB in. in.
1 0.00 32. 820 - - - - -2.500 9.230 1
2I 4.26 31.876 - - - - -1.773 8.919 i Jf
2o 4.26 31.876 0.497 0.443 0.377 0.557 0.00578 -1.773 8.9191]
3 17.39 28. 968 0.487 0.431 0.364 0.547 0.00595 0.468 7.959
4 30.52 26.060 0.474 0.415 0.349 0.534 0.00610 2.709 7.000
5 43.65 23.152 0.458 0.396 0.330 0.518 0.00630 4.950 6.040
6 56.78 20. 244 0.438 0.371 0.305 0.498 0.00661 7.191 l 1
5.081
7I 69.91 17.335 0.410 0.338 0.272 0.470 0.00692 9.432 4.122
7o 69.91 17.335 - - - - - 9. 432 4.122]
8 79.10 15.300 - ~ - - - 11.000 3.45o|I
Stab
Stab
Elev
Stab
Aerodynamic Balance Arrangement:
Elevator, internal - simple nose overhang (curtain seal)
Hinge Moment Corrections:
H a/Exp.
= 1.0
n SE: = 1.0
\ c/Exp.
AC H
cf 3
c/Exp. fAC
= 1.0
= 1.0
95
TABLE 21 (Continued)
Pressure Recovery Factor:
K = 1.0
General:
Reference half chord (b^ = 32.820 in.
cos 4> ,= 0.971554 c/4
cos ip =1.00 c
-6 2 -4 Altitude - sea level (p = 0.114626 x 10 lb. -sec. -in. )
96
k.. ~.
TABLE 22
SOLUTIONS OF STABILITY EQUATIONS
Plot: Figure 34
Uncoupled Natural Frequency, Horizontal Stabilizer Rotation: TQ; =20 cps
Spring Constants:
k =1145 lb./in. c
K = 665,400 lb.-in./rad. H
Aerodynamics: Basic Surface with Aerodynamic Balance (B / 0)
1 k
0
fi cps
vi Knots gl
f2 cps V2
Knots g2
.00 32.5 0.0 .000 20.0 0.0 .000
.15 22.7 34.7 -.060 19.1 29.2 -.054
.25 22.7 57.8 -.103 19.2 49.0 -.088
.45 22.7 103.9 -.218 19.7 90.3 -.141
.65 23.3 154.2 -.416 20.1 132.9 -.147
1.00 27.9 284.1 -1.045 20.0 203.2 -.151
2.00 - - - 18.4 374.8 -.229
4.00 - - - 14.0 570.7 -.316
(1.00 - - - 10.6 645.0 -.310
8.00 - - 8.3 673.6 -.280
11.00 _ _ — | 6.1 688.7 -.237
Uncoupled Natural Frequency, Elevator Rotation: io = 22.83 cps
97
TABLE 23
SOLUTIONS OF STABILITY EQUATIONS
Plot: Figure 35
Uncoupled Natural Frequency, Horizontal Stabilizer Rotation: fQ, =40 cps
Spring Constants:
k = 1145 lb./in. c
K-. = 2,661,800 Ib.-in./rad. n
Aerodynamics: Basic Surface with Aerodynamic Balance (B ^ 0)
1 k
0 1 cps
vi Knots gl
f2 cps
V2
Knots g2
.00 32.3 0.0 .000 40.3 0.0 .000
.15 22.1 33.8 -.095 39.3 60.0 -.019
.25 22.3 56.9 -.162 39.2 99.7 -.031
.45 23.2 106.2 -.313 38.8 177.9 -.052
.65 24.8 164.1 -.515 38.3 253.5 -.065
1.00 31.2 317.6 -1.255 37.4 381.2 -.060
2.00 - - - 35.8 728.9 -.147
4.00 _ _ • 27.4 1116.7 -.283
Uncoupled Natural Frequency, Elevator Rotation: ffl = 22.83 cps
98
TABLE 24
SOLUTIONS OF STABILITY EQUATIONS
Plot: Figure 36
Uncoupled Natural Frequency, Horizontal Stabilizer Rotation: f^ 60 cps
Spring Constants:
k = 1145 lb./in. c
K„ = 5,988,900 Ib.-in./rad. H
Aerodynamics: Basic Surface with Aerodynamic Balance (B 4 0)
1 k
o cps Knots gl
\ f2 cps V2
Knots g2
.00 32.3 0.0 .000 60.3 0.0 .000
.15 22.2 33.8 -.093 58.8 89.8 -.020
.25 22.4 57.0 -.159 58.6 149.3 -.034
.45 23.2 106.3 -.305 58.2 266.4 -.059
.65 24.8 163.8 -.498 57.4 379.7 -.079
1.00 31.1 316.2 -1.188 55.5 565.5 -.087
2.00 _ _ mm 53.1 1080.8 -.130
Uncoupled Natural Frequency, Elevator Rotation: fo = 22.83 cps
99
TABLE 25
SOLUTIONS OF STABILITY EQUATIONS
Plot: Figure 37
Uncoupled Natural Frequency, Horizontal Stabilizer Rotation: fo, = 20 cps
Spring Constants:
k = 1145 lb./in. c
K = 665,400 Ib.-in./rad. H
Aerodynamics: Basic Surface without Aeronynamic Balance (B = 0)
1 k
0
fi cps
v1
Knots gl
f2 cps
V2 Knots g2
.00 32.5 0.0 .000 20.0 0.0 .000
.15 22.7 34.6 -.064 19.1 29.2 -.054
.25 22.7 57.7 -.113 19.3 49.1 -.088
.45 22.9 104.7 -.247 19.7 90.4 -.133
.65 24.0 158.5 -.475 20.0 132.3 -.137
1.00 30.7 312.2 -1.318 19.8 201.9 -.149
2.00 - - - 18.3 372.7 -.230
4.00 - - - 14.0 569.7 -.319
6.00 - - - 10.6 645.3 -.314
8.00 - - - 8.3 674.6 -.285
11.00 - - - 6.2 690.1 -.241
Uncoupled Natural Frequency, Elevator Rotation: (o = 22.83 cps
100
TABLE 26
SOLUTIONS OF STABILITY EQUATIONS
Plot: Figure 38
Uncoupled Natural Frequency, Horizontal Stabilizer Rotation: f^ = 40 cps
Spring Constants:
k = 1145 lb./in. c
K = 2,661,800 lb.-in,/rad. H
Aerodynamics: Basic Surface without Aerodynamic Balance (B = 0)
1 k
o cps
vi Knots 61
f2 cps Knols g2
.00 32.3 0.0 .000 40.3 0.0 .000
.15 22.1 33.8 -.100 39.2 59.9 -.019
.25 22.4 57.0 -.170 39.2 99.7 -.031
.45 23.4 107.3 -.334 38.8 178.0 -.052
.65 25.4 168.1 -.567 38.3 253.4 -.064
1.00 34.4 350.5 -1.601 37.6 382.5 -.057
2.00 - - - 35.8 729.1 -.162
4.00 i _ _ _ 1 27.5 1118.6 -.290
Uncoupled Natural Frequency, Elevator Rotation: fa = 22.83 cps
101
TABLE 27
SOLUTIONS OF STABILITY EQUATIONS
Plot: Figure 39
Uncoupled Natural Frequency, Horizontal Stabilizer Rotation: f^ = 60 cps
Spring Constants:
k = 1145 lb./in. c
K = 5,988,900 lb.-in/rad. H
Aerodynamics: Basic Surface without Aerodynamic Balance (B = 0)
1 k 0
cps vi
Knots h f2 cps
v2
Knots g2
.00 32.4 0.0 .000 60.3 0.0 .000
.15 22.2 33.8 -.098 58.7 89.7 -.021
.25 22.4 57.1 -.167 58.6 149.2 -.034
.45 23.4 107.4 -.327 58.1 266.3 -.059
.65 25.4 167.8 -.548 57.3 379.4 -.079
1.00 34.3 349.6 -1.525 55.6 565.8 -.080
2.00 — m. - 53.3 1084.5 -.147
Uncoupled Natural Frequency, Elevator Rotation: fo = 22.83 cps
102
0.20
1000
Figure 34 g-V and f-V Plots, Elevator, fa = 20 cps, B ^ 0
103
a
1000
Figure 35 g-V and f-V Plots, Elevator, fa = 40 cps, B ^ 0
104
0.20
0.15
.0.10
0.05 I
Ü So
< Q
i L..-
-0.05
-0.10
-0.15
-0.20
■
:
■
■ ;
.. .
■ ■ i
: i ; ' . 1 ■
■
. ; ... :...
-.,—. — ! i : ; ■, ■ 1 , i,
; i I' :.::...,.,„|.;|. .■..,
; ... :....:.. * : i ■ T": *
; .....
1 i ; i ' i
1. i
! ■
> ... *... ...;l t ■
■ :;
i t • .... i....».-
. j , ;
1 ■ r ' »■
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i . :
■■;. i ..i : i i : l :
' ■ i i ; i I'll
ISs
. i
i' • : i .... 4 ...
i
--..(..-
i -i- ..: ; ):.;;■■. |.- : ... i • ■ t . ■
\ 1 ■ • 1 .
J.. .. i. : . : .
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■ 1: 1
— [•—
. ■ ,,,.
( ■;..;{; i. ■]:■■.■.
f ■ i
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i;T'"r
. 1. ■ ::t: '
:. i ■
• •
i •■ r
; { ■
■ ; ;
■:■.. ]■■'■
w 50 PH , Ü
1
>* 40 Ü 55
VELOCITY - KNOTS j 800 ; |:
rf—I"' 1000
Ip-ii'1':!1 iil::
Figure 36 g-V and f-V Plots, Elevator, ia = 60 cps, BfO
105
, 0,20
0.15
i
0.10
bo 0.05
Ü
< Q -0.05
•■|- i ■
-4-0. io t t
■ ■ r ;
- —0.15 i . . i i ■ ■
i ;
-'-0.20
i 1 . ; 1 " : -;•[■ •
■ ■
.... •;■:-■
r •
i
■ ■
r
I
■ i
1
1
.... *.'. i,
1 .
;...|. . A. ! i
■:,
:
: ':
■ t ■ ■
__J..... :;■,:
'. i ■. ■ ■.,.:!
'. . .1 .
. i , . .\... : . j..:: ♦-*♦-.
: :: i. '.
. * . . 1 , ' .' ,
.:• i •;:)■•: r ..
■.:! :
. ■ '' ■ ■, ,
■ ■ i ■ • •
■1 .:• • ■ ■ ■ t ...j...
■••;i ■ ■ ■ ;i ■ .
r....j.;..: •■■ 1
■1
' '. : :!i;|:::! . : 1
,...', — :,i:: '
.. i. .. ::|; r::; u ''.'. .1'.'-', ■
.: l:; ; ^.'li :
...... i i . . t ■;■•■:
, . 1 :.:!..:; ■ ■ ; •
:':". .— ,. i^ + i.., .. . t..
* *
■:: t::::
.::.!■:::
,. 1 .. .
.::: I:::.
•. .| .; :
■ •
■ ■ ■ 1 ( ■
f ■ ■
1 . ■
; ■ i , ■
<■ : ,■ ::i;-: ,,::i;':: ■ 1
■ ■ i ■ ■ ■
:l:.,:-_
■ ■: ■
"r "— ; ;.;:.;: ■ . ■1 ■ ■•
: 'IM. ,.
■: •: r::
I ... 1 • ■ ■ 1 ■
' !
. : . , : ■ ; r ■ . :. i :;"
. t.. .
i.. .
.... . . - |k ■";: ,. .
•• -i •':: . ..;..,;
::':i:;i: ■ 1
• : 1 • • .:■ r ■. |. .i .:. ;::: 1: •
|V :..:^
<:'■■■
-•; ■ 1
::' i ■: . ■ ■ . ■ . i: •,:-': ;^i:;::{.::i::i;
"♦
:^ ; ;tf;;. ::\V'^. ^•!;;;'r
• g,v - ..._ X:
1000
Figure 37 g-V and f-V Plots, Elevator, f^ = 20 cps, B = 0
106
1
I.—^_..
bß
0.20
-0.15
«0.10
0.05
-S 0-
— Q -0.05
-0.10
1 Hi
: <
'::; 1 : ■! . .: 'I
........ ^
..,;:.:.
::
■
::. ;. .
- ■ :l • .
■ ' !■■.
■ ■ ■
' ■
■■■|:,:.
■ ( ■ » ■
.: ■ r:
ru; : ■ ■: i ■ :
.»... ... i
-::- .. .....
... .. ...
1 : :i:ii:::; - -'■
..'.{. . . .'
r-.'r ■ ■■
. »■ ■ ■.• ■ ! . . .■
... i ... .
■ 1 ' ' '
. : I:/:
-:-H- ■
•!::
■*■*.■***.
:rrr ~':\: "
. > J ■
1
,.,■■.:
■ '■
r-:1- rH ■
LiiüL: : •:! :■;
■ • ■
■ ■ ■'•
■;!;■•:
■•■I " ...
* ! ■ ' i;' ■
... j.
* '- . i
: ::!:•:: , • i . . ■ ■
::;i!:;::
■' i:':
s . , • ::;; -:*rt-:r
:~ ::r
_•.•
*:•-: " sm 1 . . i . ...
• . t * * . ■ '•. ti ■ •
...j. :■
fnttr.;- : •: 1 ■::.
■ i • . . ■
"" "^ rH rM .; :
'. '. ' \\ . '. '.
.........
. t.. .
.. ■ j .'.
■ , i ■ . . .
^i.:;.
;:::!■■
..:!l:;; :.-,
1; ^r i-~
iiij . 11.. .
, i.... ....... ,
." | ■ ; .. ,.. .
.:". • i: ■:;
r T:"
: H':U rtrifjfi
. 1 1....
:::: '.'■*
[—.
(- .13 30
20
-ni;
10 -
- .:U,
UIUJ. ;F
.•.:i-u
.L^JL;
•■--:—:<■
:1"
:4. ..*;
•I ■ :
:rlr-
"-:f
L
■f--'\-
. ill. l-:i:-ri IL.^4-.- LtT
.U:L 200 i 400 ,r 600
.il;;:;!" VELOCITY- KNOTS
^: . :l:.L:
:{"-;
rrtirt-r-
■r:'
■r-
800 iÜi 1000
Figure 38 g-V and f-V Plots, Elevator, fa = 40 ops, B - 0
107
. .1
bfi l
Ü
0.20
.0.15
•0.10
0.05
- £ - 0
< Q -0.0511
■ ■ ■ i ■
-0.10
-..l._ 0.15
-0.20
-T-J-- ■
■
. . .:
■
■
...... .,. ...... ... ■
:
- -►•-:,-' •-■'
■-- .;
■ (
.....
. 1 .: ■ ~
. l i. : ;:i;::';
..'
— . I . . I..!' . i..
...:.:.. ' '".
::** ""':
'..:' ■ -IT: -I- ;. :1 ..:
' v:
.: j...
; * . ■:
:;: I:.:
. . . . , . . . :. t: .. .
. . . . 1 . . .
■*■»■■■ •-: •■*::
■ ■
HH|r -•• :._.3 : ■;|::. . . . 1 ...
-* -—♦-*—• ► ::r
i • ... i—
: i
1—;—..
... .. ;: . ■ ■
>.
■ .. t., . ■ ■ t
f. -:■:: ....... . •:. i ■ •: ■
:-r ■ 1
S •■1
:::: j;
.«t. —»<*— rrtf i:::;
: :
:3 u:.: i
:••):•: [ • ■ >
■;;::: ..... frrr
■' * ♦
:;:-
(..:■
.... ( .:;: ^•X» — ■-
t;:.'
'/■''■ '■'■'■■ ß ! , ■ i ' ' '
I." ■ '
...|....v ;• ;
:::: "•■:
'--'- 2:'i '■ :
... . ■ » . . f ■-■::;!
■'(■•••
: ::!:••: - .^4.-..^
, 1 . . . . trrf ^ •-f1
1
I:': ■■-■, ::
. ♦..
.,', I.: . .!,..■ — .: i, ..
J\ev;r :;;: : ■ *: 1: . 1-^ . __.t^ ^i-u ■l-\\l:l
jl-. ■
i (,.,.
. ■: i: :. ; ; 1. ! . : ; ;;i:;:; ::::[:::: :::;1:;;',
: looo
Figure 39 g-V and f-V Plots, Elevator, fa = 60 cps, B = 0
*
108
I I t I
kt^fl.
5.0 CONCLUSIONS AND RECOMMENDATIONS
Flutter analyses of all XV-5A control surfaces have been made, based on preliminary input information. Increased stiffness of the aileron control circuit ( the symmetric aileron condition is critical) is re- quiiod, and the stiffness of the rudder trim tab actuator should be such that the uncoupled rigid body tab rotational frequency is at least 50 cps in order to ensure a flutter-free airplane within the estab- lished flight envelope. The antisymmetric aileron condition and elevator are flutter-free.
It is recommended that further flutter analysis of all control surfaces be made on the basis of refinements to stiffness and inertia proper- ties as the design develops, incorporating experimentally determined properties as they become available. It is recommended that the report herein be used as intended: for interpretive purposes as an aid to design development and not as a definitive prediction of control system flutter performance. Further, this report can and should be used in con- junction with the formulation of main surface flutter analyses (wing, and empennage, for example ) to determine important control surface degrees of freedom that should be considered in the main surface analyses.
109
f'ttt
6.0 APPENDIX
6.1 REFERENCES
1. Krupnlck, M. - Model 30 (CV-600) Airplane Tab Flutter Analysis, General Dynamics/Convair Report ZU-30-004, 15 September 1960.
2. Smilg, B., and Wasserman, L. S. - Application of Three- Dimensional Flutter Theory to Aircraft Structures, Air Force Technical Report 4798, 1942.
3. Wasserman, L. S., Mykytow, W. J., and Spielberg, I. N. - Tab Flutter Theory and Applications, Air Force Technical Report 5153, 1944.
4. Ashley, H. - Subsonic Flutter of a Control Surface with a Balance Board, General Dynamics/Convair Memo DG-G-177, 30 July 1957.
in
Recommended